Recombinant C-terminal α-amidating enzyme

ABSTRACT

A C-terminal α-amidating enzyme of  Xenopus laevis  and precursor thereof produced by a recombinant DNA technique; a DNA coding for the enzyme or precursor thereof; a plasmid containing the DNA; a host organism transformed with the plasmid; a process for production of the enzyme using the transformant; and a process for production of a C-terminal α-amidated peptide using the enzyme.

This application is a divisional of application Ser. No. 07/219,375, filed Jul. 15, 1988.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to recombinant C-terminal α-amidating enzymes of Xenopus laevis origin and precursors thereof, DNAs coding for these poly-peptides, plasmids containing the DNA, host cells transformed with the plasmid, a process for the production of the enzyme or precursor thereof using the transformed cells, and a process for the production of a C-terminal α-amidated peptide or protein using the enzyme.

2. Related Art

It is generally known that, in eukaryotic cells, some kinds of peptides or proteins are, after translation from a messenger RNA (mRNA), modified by an intracelular enzyme to mature to a natural-type peptide or protein (post-translational modification). But, since prokaryotic hosts such as E. coli, which are widely used to produce peptides or proteins of eukaryote origin, cannot carry out a post-translational modification of an expressed peptide or protein, it is sometimes difficult to directly produce a eukaryotic peptide or protein by a recombinant DNA technique using prokaryotic host cells.

One of this post-translational modification characteristic of eukaryotic cells of peptides or proteins is a modification reaction wherein an α-position of a carboxy terminal (C-terminal) of a peptide or protein is amidated, i.e., —COOH is converted to —CONH₂, and it is known that many physiologically active peptides or proteins have been subjected to such modification. For example, as C-terminal α-amidated peptides, TRH(pGlu-His-Pro-NH₂) and Caerulein

have been isolated, and a partial structure of precursors of these peptide determined from an analysis of the cDNA thereof. A general biosynthesis mechanism of such amidated peptides is understood to be that in which RNA is translated to a precursor of an amidated peptide, which is then amidated at the α-position of the C-terminal thereof by a C-terminal α-amidating enzyme. Note, in the above-mentioned reaction, the precursor of the C-terminal α-amidated peptide as a substrate for a C-terminal α-amidating enzyme is a peptide or protein represented by a general formula R-X-Gly, wherein R represents an amino acid sequence of the N-terminal side of the peptide or protein, X represents an amino acid residue which is to be α-amidated at the C-terminal thereof, and Gly represents a glycine residue.

It is known that, in some cases, the above-mentioned modification of peptide or protein is essential to the physiological activity thereof. For example, a conversion of the proline amide residue at the C-terminal of natural-type human calcitonin to proline residue decreases the physiological activity thereof to {fraction (1/1,600)} of the original activity.

Because of the importance of clarifying the mechanism of α-amide formation in tissues, and the promising usefulness of the enzyme for the production of C-terminal α-amidated peptides using, for example, recombinant DNA techniques, many attempts to purify the enzyme have been made but the enzyme has not so far been obtained in a pure state. In porcine pituitary, Bradburg, A. F. et al, Nature 298, 686-688, 1982, first characterized the α-amidating activity converting a synthetic substrate D-Tyr-Val-Gly to D-Tyr-Val-NH₂, and demonstrated that the C-terminal glycine in the substrate serves as a nitrogen-donor for α-amidation. Eipper et al, Proc. Natl. Acad. Sci. US, 80, 5144-5148, 1983, reported that the α-amidating enzyme derived from the pituitary gland requires copper cation and ascorbate for its activity. Husain, I. et al, FEBS Lett., 152 227-281, 1983; and Kizer, J. S. et al, Proc. Natl. Acad. Sci. US, 81, 3228-3232, 1984, also reported a C-terminal α-amidating enzyme, but did not report a purified enzyme. Recently, Murthy A. S. N. et al, J. Biol. Chem., 261, 1815-1822, 1986, partially purified a C-terminal α-amidating enzyme from the pituitary gland of cattle, and showed that several types of enzymes having different molecular weights and electric charges are present. Nevertheless, no type of enzyme has been homogeneously purified.

Recently, Mizuno et al. succeeded in isolating a C-terminal α-amidating enzyme in a homogeneous and pure form from a skin of Xenopus laevis; see Mizuno, K et al, Biochem. Biophys. Res. Commun. 137, 984-991, 1988, and Japanese Patent Application No. 61-131089.

Nevertheless, the amount of the C-terminal α-amidating enzyme isolated from a skin of Xenopus laevis is limited, and not sufficient for use in the industrial production of C-terminal α-amidated peptides or proteins.

SUMMARY OF THE INVENTION

Accordingly, the present invention provides a recombinant DNA technique for the production of a C-terminal α-amidating enzyme and the large amount of thus-produced enzyme, as well as the use of the enzyme for the production of C-terminal α-amidated peptides or protein.

More specifically, the present invention provides a C-terminal α-amidating enzyme of Xenopus laevis and precursors thereof produced by a recombinant DNA technique.

The present invention also provides a DNA coding for a C-terminal α-amidating enzyme of Xenopus laevis or precursor thereof.

Further, the present invention provides a plasmid containing a DNA coding for a C-terminal α-amidating enzyme of Xenopus laevis or precursor thereof.

Moreover, the present invention provides host organisms transformed with a plasmid containing the DNA coding for a C-terminal α-amidating enzyme of Xenopus laevis or precursor thereof.

Still further the present invention provides a process for the production of a C-terminal α-amidating enzyme of Xenopus laevis and precursor thereof comprising the steps of, culturing a host organism transformed with a plasmid containing a DNA coding for the enzyme or precursor thereof to produce the enzyme or precursor thereof, and recovering the enzyme or precursor thereof.

Also, the present invention provides a process for the production of a C-terminal α-amidated peptide or protein characterized by reacting the above-mentioned enzyme with a peptide or protein having a glycine residue at the C-terminal thereof.

BRIEF EXPLANATION OF THE DRAWINGS

FIGS. 1A to 1E show an entire nucleotide sequence of cDNA in a plasmid pXA457 and an amino acid sequence encoded by the cDNA, which nucleotide sequence contains a nucleotide sequence coding for an amino acid sequence of a first type of prepro-C-terminal α-amidating enzyme as well as a 5′-terminal and 3′-terminal non-coding sequences;

FIGS. 2A to 2C show an amino acid sequence of a C-terminal α-amidating enzyme which corresponds to the first amino acid to the 344th amino acid in FIGS. 1A to 1D, and a corresponding nucleotide sequence;

FIGS. 3A to 3C show an amino acid sequence of a pre-C-terminal α-amidating enzyme which corresponds to the first amino acid to the 363th amino acid in FIGS. 1A to 1D, and a corresponding nucleotide sequence;

FIGS. 4A to 4D show an amino acid sequence of a prepro-C-terminal α-amidating enzyme which corresponds to the −37th amino acid to the 363th amino acid in FIGS. 1A to 1D, and a corresponding nucleotide sequence;

FIG. 5 shows an N-terminal amino acid sequence (T-Term) of a native C-terminal α-amidating enzyme isolated from a skin of Xenopus laevis, and amino acid sequences of tryptic fragments (T-numbers) of the native enzyme;

FIG. 6 shows a design of mixed probes YS012, YS013, and YS015 used for isolation of a cDNA coding for a C-terminal α-amidating enzyme derived from Xenopus laevis, on the basis of amino acid sequences of the tryptic fragments T-11 and T-30;

FIGS. 7A and 7B show a restriction enzyme cleavage map (7A) of cDNA in the plasmid pXA457, and a strategy used to determine a nucleotide sequence of the cDNA (7B);

FIG. 8 shows a construction process of a plasmid pUCl8XA (EcoRI);

FIG. 9 shows a construction process of a plasmid ptrpXAST4;

FIG. 10 shows a construction process of a plasmid ptrpXAST8 for the expression of an enzyme XA;

FIG. 11 shows a design of a DNA linker F;

FIG. 12 shows a construction process of a plasmid ptrpXDAST4;

FIG. 13 shows a construction process of a plasmid ptrpXDAST8 for the expression of an enzyme XDA;

FIGS. 14A-14B show (14A) a result of an SDS-PAGE for total proteins from E. coli W3110, E. coli W3110/ptrpXAST8, and E. coli W3110/ptrpXDAST8, and (14B) a comparison of the molecular weights of an enzyme XA, an enzyme XDA, and a native enzyme by SDS-PAGE;

FIG. 15 shows a result of an assay of the enzymes XA and XDA for C-terminal α-amidating enzyme activity;

FIGS. 16A to 16F show a nucleotide sequence of cDNA in a plasmid pXA799, and an amino acid sequence coded by the cDNA. The cDNA contains a nucleotide sequence coding for a second type of C-terminal α-amidating enzyme;

FIG. 17 shows a comparison of restriction enzyme cleavage maps of cDNA in the plasmid pXA457 and cDNA in the plasmid pXA799;

FIG. 18 shows a strategy used to determine a nucleotide sequence of cDNA in the plasmid pXA799;

FIGS. 19A to 19B shows a comparison of primary amino acid sequences of proteins coded by cDNA's in plasmids pXA457 and pXA799;

FIG. 20 shows a protein coded by cDNA in pXA799 and derivatives thereof, as well as corresponding plasmids;

FIG. 21 shows a construction process of a plasmid pXA799(EcoR I);

FIG. 22 shows a construction process of a plasmid pUCP_(L)CI;

FIG. 23 shows a construction process of a plasmid pUCP_(L)CI799Dra I;

FIG. 24 shows a construction process of a plasmid pUCP_(L)CI799Bgl II;

FIG. 25 shows a construction process of a plasmid pUCP_(L)CI799R V;

FIG. 26 shows a construction process of a plasmid pUCP_(L)CI799Sal I;

FIG. 27 shows a construction process of a plasmid pUCP_(L)CI799BstE II^(L);

FIG. 28 shows a construction process of a plasmid pUCP_(L)CI799BstE II^(S);

FIG. 29 shows a construction process of a plasmid pXA799 (EcoRI-Sal I);

FIG. 30 shows a construction process of a plasmid ptrpΔ799; and,

FIG. 31 shows a construction process of a plasmid ptrp799-459Δ

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present inventors isolated a C-terminal α-amidating enzyme in homogeneous pure form from a skin of Xenopus laevis, and determined partial amino acid sequences of the enzyme. Next, DNA probes were prepared on the basis of the partial amino acid sequences, and the probes were used to screen a cDNA library derived from a skin of Xenopus laevis to obtain a single clone containing a cDNA coding for a C-terminal α-amidating enzyme.

Moreover, the entire primary amino acid sequence of a C-terminal α-amidating enzyme (see FIGS. 2-1 to 2-3) and precursors thereof, i.e., pre-enzyme (FIG. 3-1 to 3-3) and prepro-enzyme (FIG. 4-1 to 4-3), were determined on the basis of the nucleotide sequence of the cDNA. Next, the cDNA was tailored and introduced into a plasmid to construct an expression plasmid, which was then transformed into E. coli cells to economically produce a large amount of the C-terminal α-amidating enzyme.

As mentioned above, although it was known that a skin of Xenopus laevis contains at least TRH and caerulein as C-terminal α-amidated peptides, it was not clear whether these C-terminal α-amidated peptide were synthesized only by the above-mentioned C-terminal α-amidating enzyme. In other words, there was a possibility that other enzymes having an activity similar to that of the above-mentioned enzyme present in a skin of Xenopus laevis and different C-terminal α-amidated peptides or proteins were biosynthesized by a different C-terminal α-amidating enzyme. Accordingly, the present inventor again attempted to screen a cDNA library derived from a skin of Xenopus laevis using the above-mentioned cDNA as a probe, and as a result, the present inventor identified another cDNA coding for an enzyme which has an activity similar to that of the above-mentioned C-terminal α-amidating enzyme but has an amino acid sequence different from that of the above-mentioned enzyme, and further, succeeded in expressing the second enzyme.

Moreover, the present inventors developed a process for the production of a C-terminal α-amidated peptide or protein from a substrate peptide or protein having a glycine residue at the C-terminal thereof.

In the present invention, a C-terminal α-amidating enzyme is an enzyme which converts a peptide or protein represented by the formula R-X-Gly, wherein R represents an amino acid sequence of the N-terminal side of the peptide or protein, X represents an amino acid residue which is to be α-amidated at the C-terminal thereof, and Gly represents a glycine residue to a peptide or protein represented by the formula R-X-NH₂, wherein R and X have the same meanings as defined above.

A C-terminal α-amidating enzyme of Xenopus laevis origin includes an enzyme which is present in a skin of Xenopus laevis and has the above-mentioned enzyme activity, and modified proteins wherein at least one amino acid of a native enzyme is deleted, or replaced with another amino acid(s), or at least one amino acid is added to the native enzyme.

The present invention is now described in more detail.

(1) Purification of a C-terminal α-amidating Enzyme and Determination of a Partial Amino Acid Sequence of the Enzyme

A C-terminal α-amidating enzyme is purified in a homogeneous form from a skin of Xenopus laevis according to a method disclosed by Mizuno et al., in Biochem. Biophys. Res. Commun. 137, 984-991, 1986. Hereinafter, this enzyme is referred to as a “native enzyme”. More specifically, a skin of Xenopus laevis is washed with an appropriate buffer and disrupted by a physical means, to elute the enzyme, and the enzyme is recovered and purified from the resulting eluate.

Next, the enzyme is hydrolyzed with trypsin to generate peptide fragments (tryptic fragments) which are then fractionated and purified by reverse phase high performance liquid chromatography (HPLC). An amino acid sequence of each tryptic fragment is determined by a protein sequencer. On the other hand, an N-terminal amino acid sequence of the native enzyme is determined from the native enzyme by a protein sequencer. (See FIG. 5)

(2) Isolation of cDNA of C-terminal α-amidating Enzyme

A total RNA mixture is prepared from a skin of Xenopus laevis according to a conventional procedure, and poly (A) RNA is prepared from the total RNA using an oligo (dT) cellulose column. Next, cDNA is prepared from the thus-prepared poly (A) RNA according to a method of Gubler, V. and Hoffman, B. J., Gene 25, 263, 1983, and the cDNA is transfected into an E. coli K12-derived strain DH1 to construct a cDNA library of Xenopus laevis origin. To isolate a cDNA coding for a target C-terminal α-amidating enzyme from the cDNA library, oligonucleotide probe mixtures, for example, YS012, YS013, YS015 and the like (see FIG. 6) are prepared on the basis of partial amino acid sequences such as T-11, T-30, and the like (see FIG. 5).

Next, each probe mixture is labeled at the 5′-terminal thereof using [γ-³²P]ATP and T₄ poly-nucleotide kinase, and the labeled probe mixtures are then used to screen the cDNA library in an E. coli K12-derived strain DH1 to obtain a single cDNA clone, such as E. coli DH1/pXA457, coding for a C-terminal α-amidating enzyme of Xenopus laevis.

Further, a DNA probe is prepared by radio-labeling a cDNA fragment coding for a part of a C-terminal α-amidating enzyme, for example, a PvuII cDNA fragment from the 54th nucleotide C to the 795th nucleotide G in the plasmid pXA457 shown in FIG. 1-1 to 1-2, through nick-translation using [α- ³²P]CTP. The probe thus prepared is used to screen the cDNA library in an E. coli K12-derived strain DH1 to obtain another single clone, for example E. coli DH1/pXA799, containing cDNA coding for a C-terminal α-amidating enzyme different from the above-mentioned enzyme.

(3) Analysis of cDNA Coding for C-terminal α-amidating Enzyme

According to a conventional procedure, a plasmid such as pXA457 is isolated from the above-mentioned single clone, and the plasmid is cleaved with various kinds of restriction enzymes to make a restriction enzyme cleavage map of the cDNA (see FIG. 7(a)). Next, each cDNA fragment generated by restriction enzymes is sub-cloned into M13 phage, and a nucleotide sequence of a cDNA insert in each clone is determined by a method of Sanger F. et al., Proc. Natl. Acad. Sci. USA, 34, 5463-5467 (1977) (see FIG. 7(b)).

An analysis of a nucleotide sequence of the cDNA in the plasmid pXA457 revealed that:

1) the cDNA contains a long open reading frame starting with the first nucleotide and terminating at the 1200th nucleotide in FIGS. 1-1 to 1-3;

2) a primary amino acid sequence expected from this open reading frame consists of 400 amino acid residues starting with the N-terminal Met-Ala-Ser- and ending at the C-terminal -Ser-Ala-Val; and

3) this primary amino acid sequence contains all of the above-mentioned partial amino acid sequences (amino acid sequences of tryptic fragments shown in FIG. 5) of the native enzyme. The above-mentioned analysis shows that the plasmid pXA457 contains a cDNA coding for an entire amino acid sequence of the target enzyme.

The N-terminal amino acid sequence of the native enzyme has already been determined from an analysis of protein level as Ser-Leu-Ser-Asn-Asp-(FIG. 5). This amino acid sequence corresponds to an amino acid sequence starting with Ser (1) in an amino acid sequence expected from the nucleotide sequence of cDNA, as shown in FIG. 1-1, and therefore, an amino acid sequence portion from Met (−37) to Arg (−1) underlined in FIG. 1-1 in the amino acid sequence expected from the nucleotide sequence is assumed to be a signal sequence necessary for a secretion of protein. The presence and function of a signal sequence has been already clarified in many other secretion proteins, and accordingly, it is expected that a the native enzyme is first synthesized from Met (−37), and the peptide portion from Met (−37) to Arg (−1) is removed by a signal peptidase or other processing enzyme to produce the native enzyme.

Although the C-terminal amino acid sequence of native enzyme expected from cDNA analysis is -Ser-Ala-Val-OH, the C-terminal amino acid sequence at protein level has not yet been determined. Accordingly, to determine the C-terminal structure of the native enzyme, the present inventor carried out the following experiments.

First, since the N-terminal amino acid sequence has been determined as Ser-Leu-Ser-, if the C-terminal amino acid sequence is Ser-Ala-Val-OH, as assumed from the cDNA, a theoretical molecular weight of the native enzyme calculated from an amino acid sequence expected from the cDNA is 40114, which is larger than a molecular weight of about 39000 obtained from a native enzyme purified from Xenopus laevis by SDS-PAGE analysis.

Moreover, in a comparison between an amino acid composition of native enzyme which has been determined by amino acid analysis and set forth in Table 1, and a theoretical amino acid composition calculated from an amino acid sequence expected from cDNA, it was found that the number of glutamic acid residues and the number of leucine residues determined by amino acid analysis are lower than those calculated from the nucleotide sequence, by 4 to 5, and 3 respectively. On the other hand, the amino acid sequence expected from the cDNA contains a sequence Lys (344)-Arg (345) at a position near the C-terminal, and it is known that this amino acid sequence is a recognizing site for a processing enzyme (protease) in precursors of many physiologically active peptides, and that this site is cleaved to convert the precursors to physiologically active mature peptides. Therefore, in the case of the present C-terminal α-amidating enzyme, it is likely that a peptide linkage between Lys (344)-Arg (345) is cleaved to convert a precursor peptide to the native enzyme. This speculation conforms to the facts that:

1) an amino acid composition calculated for an amino acid sequence from Ser (1) to Lys (344) is similar to an amino acid sequence determined from the native enzyme;

2) a theoretical molecular weight calculated from the amino acid sequence from Ser (1) to Lys (344) is similar to a molecular weight determined from a native enzyme; and

3) the amino acid sequence: H-Asn-Thr-Gly-Leu-Gln-Gln-Pro-Lys-OH of the tryptic fragment T-9 corresponds to an amino acid sequence: Asn(337)-Thr(338)-Gly(339)-Leu(340)-Gln(341)-Gln(342)-Pro(343)-Lys(344) expected from the cDNA.

Accordingly, to prove the above-mentioned possibility, the present inventors carried out the following experiments: (1) expression of cDNA portions of nucleotides 112 to 1200, and of nucleotides 112 to 1143 (the nucleotide numbers correspond to those in FIGS. 1-1 to 1-4), in E. coli; (2) comparison of molecular weights of two proteins expressed in E. coli as above and the native enzyme by SDS-PAGE; and (3) separation of the proteins expressed in E. coli by SDS-PAGE and isolation of the target proteins from the gel, determination of the amino acid compositions of these proteins, and comparison of the amino acid compositions with that of the native enzyme. As a result, it was strongly suggested that a primary amino acid sequence of the native enzyme is identical to a primary amino acid sequence coded by a cDNA portion (112-1143) in pXA457 (see Table 1 and FIG. 14(b)).

According to the same procedure as described above for the first plasmid pXA457, another plasmid pXA799 is isolated from a second single clone selected from a cDNA library using the first cDNA as a probe. Next, a restriction enzyme cleavage map of cDNA in the plasmid pXA799 is made, and a nucleotide sequence of the cDNA is determined. The result is shown in FIGS. 16-1 to 16-3. An analysis of the result revealed the following:

1) The cDNA contains a long open reading frame starting with the nucleotide and terminating at 2625 of the nucleotide in FIGS. 16-1 to 16-3, and coding a protein consisting of 875 amino acid residues. Note, since a translation stop codon TAA is present at position-18 to -16 in FIG. 16-1, methionine coded by nucleotides No. 1 to 3 in FIG. 16-1 is a translation start codon of this protein.

2) As shown in FIG. 19-1 to 19-2, in a comparison of a primary amino acid sequence of a protein coded by the cDNA in pXA799 and a primary amino acid sequence of a prepro-C-terminal α-amidating enzyme coded by cDNA in pXA457, an N-terminal side (amino acid No. −37 to 350) of the protein coded by the cDNA in pXA799 is very similar to that for pXA457. Note, the similarity between the above-mentioned two primary amino acid sequences is conserved at processing sites, i.e., N-terminal site and C-terminal site, of precursor proteins.

3) Nevertheless, the C-terminal side of the protein coded by cDNA in pXA799 is completely different from that of pXA457. Namely, the open reading frame in the cDNA in pX7799 is largely extended to the 3′-terminal.

4) The extended portion contains a three Asn-X-Ser sequence wherein X represents any amino acid residue, corresponding to an amino acid number 426-428, 623-625, and 704-706 in FIG. 16-2-16-3. The sequence Asn-X-Ser is known to be a N-glycosylation site in many glycoproteins, and therefore, a protein coded by the cDNA in pXA799 is also likely to be N-glycosylated.

5) The protein coded by the cDNA in pXA799 contains a region from the amino acid number 727 to 748 comprising hydrophobic amino acids, as well as basic amino acids, i.e., arginine and lysine immediately after the hydrophobic region. Since a similar structure has been identified in many membrane proteins at the transmembrane domain thereof, the protein coded by the cDNA in pXA799 is likely to be present as a membrane protein.

From the above-mentioned analysis of cDNA in pXA799, and of a primary amino acid sequence coded by the cDNA, the protein coded by the cDNA in pXA799 is completely different from the C-terminal α-amidating enzyme coded by the cDNA in pXA457. But, so far, a protein expected from the cDNA in pXA799 has not been isolated and purified from Xenopus laevis. Therefore, the mechanism of biosynthesis of a protein expected from the cDNA in pXA799 (cleavage of N-terminal and C-terminal, presence or absence of glycosylation, etc.), the location in vivo of the protein, as well as the function of the protein (presence or absence of C-terminal α-amidating activity) are not clear. Therefore, to clarify these questions, the present inventors used the cDNA in pXA799 to express in E. coli a protein coded by the cDNA and protein derivatives thereof, and the C-terminal α-amidating activities of these proteins were measured.

From a comparison of the cDNA in pXA457, the cDNA in pXA799, and the N-terminal amino acid sequence of the native enzyme, it is considered that a peptide portion from amino acid number −39 to −1 in FIG. 16-1 is a signal peptide necessary for secretion of the protein, and a peptide bond between amino acid −1 and amino acid 1 is cleaved during biosynthesis of a mature protein. Therefore, a mature protein corresponding to a protein coded by the cDNA in pXA799 starts with the amino acid 1 in FIG. 16-1, and has an N-terminal amino acid sequence: H-Ser-Leu-Ser-Asn-Asp- - - - .

But, with regard to a mechanism for a biosynthesis of a C-terminal portion, the glycosylation, post-translation modification such as a cleavage of the C-terminal portion, and the relationship between the C-terminal structure and C-terminal α-amidating activity, have not been known. To clarify these points, a full length peptide starting from amino acid 1 and terminated at amino acid 836, i.e., having an amino acid sequence H-Ser(1)-Leu-Ser-Asn-Asp- - - - -Pro-Pro-Val-Ser-Ser-Ser-OH(836), and various peptides starting from amino acid 1 and having a shortened C-terminal terminated at different sites, are expressed in E. coli, and the enzyme activity of each protein is determined. FIG. 20 schematically shows structures of these proteins, names of the plasmids used for the expression of these proteins, and the enzyme activity. Note, in some cases, since a multi-cloning site is introduced into an expression plasmid during construction of the plasmid, the protein has a C-terminal amino acid sequence different from the amino acid sequence of pXA799 origin. In such a case, the different amino acid sequence is shown in FIG. 20 for each protein.

(4) Expression of C-terminal α-amidating Enzyme in Host Cells

To express a C-terminal α-amidating enzyme coded by cDNA derived from pXA457 in host cells such as E. coli, expression vectors such as ptrpXAST8 and ptrpXDAST8 are constructed. These expression vectors are designed to express cDNA under the control of an appropriate expression control sequence, for example, a tryptophan operon functional in host cells such as E. coli (promoter, operator, and Shine-Dalgarno sequence of tryptophan leader peptide). Next, the expression vector is used to transform host cells such as E. coli W3110 to obtain transformations such as E. coli W3110/ptrpXAST8 and E. coli W3110/ptrpXDAST8.

On the other hand, to express a C-terminal α-amidating enzyme coded by cDNA derived from pXA799, expression vectors such as pUCP_(L)CI799Dra I, pUCP_(L)CI799Bgl II, pUCP_(L)CI799R VI pUCP_(L)CI799Sal I, pUCP_(L)CI799BstE II^(L), pUCP_(L)CI799BstE II^(S), ptrpΔ799, ptrp799-457Δ, and the like are constructed. These expression vectors are designed to express a protein coded by the cDNA in pXA799, or shortened protein derivatives under an appropriate expression control sequence such as λ phage P_(L) promoter for pUCP_(L)CI series plasmids, or an E. coli tryptophan promoter for ptrp series plasmids. Next, these vectors are used to transform host cells such as E. coli W3110, to obtain transformants for expression, such as E. coli W3110/PUCP_(L)CI799Dra I, E. coli W3110/pUCP_(L)CI799Bgl II, E. coli W3110/pUCP_(L)CI799R V, E. coli W3110/pUCP_(L)CI799Sal I, E. coli W3110/pUCP CI799BstE II^(S) , E. coli W3110/pUCP_(L)CI799 BstE II^(L) , E. coli W3110/ptrp 799 and E. coli W3110/ptrp799-457Δ).

Next, these transformants and the control E. coli W3110 are separately cultured, cultured cells are collected, and the whole protein in the cultured cells is analyzed by SDS-acrylamide gel electrophoresis (SDS-PAGE). As a result, it was found that E. coli W3110/ptrpXAST8 and E. coli W3110/ptrpXDAST8 produced specific proteins having molecular weights of about 40 K and about 38 K, compared to total protein produced by a control E. coli W3110. Other transformants are also confirmed to produce target proteins.

Most of the portion of a protein thus expressed is recovered in a precipitation fraction in a conventional cell disruption process, such as ultra-sonication or French press disruption.

(5) Assay of Enzyme Activity

A C-terminal α-amidating enzyme activity is assayed to confirm that a protein expressed in a transformant host is a C-terminal α-amidating enzyme, and that when a C-terminal α-amidating enzyme acts on the substrate thereof, an amidated peptide or protein is produced. For an assay of an expression of an enzyme in E. coli, E. coli cells are disrupted and the disruptant is centrifuged to obtain a precipitate containing a major portion of the expression product, the precipitate is solubilized with 6 M guanidine hydrochloride, and the solution thus obtained is dialyzed to obtain an assay sample.

Enzyme activity is assayed by using a reaction wherein a substrate generally represented by R-X-Gly is converted to R-X-NH₂, for example, a reaction wherein a synthetic substrate [¹²⁵I]-Ac-Tyr-Phe-Gly is converted to [¹²⁵I]-Ac-Tyr-Phe-NH₂.

Namely, first a labeled substrate (labeled R-X-Gly) is subjected to a reaction with a test enzyme solution in Tris-HCl buffer, to this reaction mixture are added Tris-HCl buffer and ethyl acetate, and after mixing, the whole is centrifuged to separate an organic phase and an aqueous phase. Since a major portion of the unreacted labeled substrate (labeled R-X-Gly) transfers to an aqueous phase, and an amidated labeled products (labeled R-X-NH₂) transfers to an organic phase, the substrate and the product can be easily separated.

In examples of the present invention, a C-terminal α-amidating enzyme of the present invention was assayed using synthetic peptide.

[¹²⁵I]-Ac-Tyr-Phe-Gly as a substrate according to the following procedure. [¹²⁵I]-Ac-Tyr-Phe-Gly (1 pmole, 70,000-150,000 cpm) was incubated with an enzyme preparation, in a final volume of 250 μl containing 0.2 M Tris-HCl buffer (pH 7.0), 2 μM CuSO₄, 0.25 mM ascorbic acid, 25 μg catalase (Boehringer), 0.1% Lubrol (PX type, Nakarai Chemicals). The reaction mixture was kept at 37° C. for 1 to 4 hours, and then 0.75 ml of 1 M Tris-HCl buffer (pH 7.0) and 2 ml of the organic phase of an ethyl acetate/water mixture was added. The two phases were mixed vigorously in a Vortex mixer, and after centrifugation at 3000 rpm for 3 mins, the organic phase thus separated was transferred to another test tube. The radioactivity in the organic and aqueous layers was measured by a gamma scintillation counter. Under the conditions described above, over 98% of the radioactivity of the authentic [¹²⁵I]-Ac-Tyr-Phe-Gly was retained in an aqueous phase and over 98% of the radioactivity of the authentic [¹²⁵I]-Ac-Tyr-Phe-NH₂ was transferred to an organic phase.

The yield of conversion is calculated from the ratio of the radioactivity in an organic phase such as an ethyl acetate phase to the total radioactivity. In this assay, one unit is defined as the enzyme activity that gives fifty percent conversion of 1 p mole substrate, such as [¹²⁵I]-Ac-Try-Phe-Gly, to [¹²⁵I]-Ac-Tyr-Phe-NH₂.

Where a crude extract from the skin of Xenopus laevis is assayed, the above-mentioned ethyl acetate layer is purified by reserve-phase HPLC using a μBondapak C-18 column, (Waters) before measurement of the radioactivity. Elution is carried out with a linear gradient of CH₃CN concentration from 10 to 50% in 10 mM ammonium formate (pH 4.0) at a flow rate of, for example, 2.0 ml/min. A peak of radioactivity appears at the same position on that of an authentic peptide having the formula R-X-NH₂, under the same condition. This means that the labeled R-X-Gly is converted to the labeled R-X-NH₂, and therefore, the expressed protein has a C-terminal α-amidating activity.

(6) Process for α-amidation of Peptide

The present enzyme products can be used to α-amidate a peptide. In this process, a substrate peptide having a glycine residue at the C-terminal thereof is incubated with one of the present enzyme products in an aqueous reaction medium, preferably in an aqueous buffer such as Tris-HCl, at a pH of about 6 to 7, and at a temperature of about 37° C., for a time sufficient to convert a substantial amount of the starting peptide to a corresponding C-terminal α-amidated peptide.

Although the present invention is directed to a C-terminal α-amidating enzyme of the skin of Xenopus laevis, other various kinds of animal tissue have been known to contain a similar enzyme activity. The properties of these enzymes are similar to those of the enzyme of the present invention, in that they require Cu⁺⁺ ion for their activity; they are inhibited by a thiol compound such as dithiothreitol; the enzyme activity is lowered in the absence of ascorbic acid; and they require molecular oxygen. Therefore, it is presumed that the amino acid sequences of active domains of these enzymes are conserved, and accordingly, the cDNA of the present invention could be used as a probe to screen the mRNA or cDNA of other animals, to identify an mRNA or cDNA coding for enzymes similar to the present enzyme.

Although the present invention discloses in detail a process for the production of a C-terminal α-amidating enzyme using the cDNA in an E. coli host, the present cDNA can be used to express the target enzyme in another host, such as yeast or animal cells. Moreover, since various kinds of derivatives of the enzyme can be prepared by the present invention, it is expected that other modified proteins, such as proteins wherein one or more than one amino acid is added, proteins wherein one or more than one amino acid is deleted, and proteins wherein one or more than one amino acid is replaced by another amino acid(s), would exhibit a C-terminal α-amidating activity. Accordingly, the present enzymes include, in addition to the enzymes coded by the cDNA of Xenopus laevis, modified proteins having a C-terminal α-amidating activity.

As described above, the present inventors isolated the cDNA coding for a C-terminal α-amidating enzyme from the skin of Xenopus laevis, clarified the structure of the cDNA, and provided a process for the production of the above-mentioned enzyme. The cDNA can be used not only in a bacterial host such as E. coli but also in a eukaryotic host such as yeast or animal cells, to produce a large amount of the target enzyme. Moreover, the present enzyme can be used to produce physiologically active peptides having a C-terminal α-amide from precursor peptides having glycine at the C-terminal thereof, which precursor peptide may be produced by a recombinant DNA technique, chemical methods, or isolated from a natural source.

EXAMPLES

The present invention will now be further illustrated by, but is no means limited to, the following examples.

Example 1 Amind Acid Composition and Partial Amino Acid Sequence of C-terminal α-amidating Enzyme (Native enzyme) Derived from Skin of Xenopus laevis

A C-terminal α-amidating enzyme of the skin of Xenopus laevis was purified according to a method of Mizuno, K. et al, Biochem. Biophs. Res. Commun. 137, 984-991, 1986. Namely, Frog skins dissected out from Xenopus laevis were homogenised with a Polytron homogenizer in 10 mM Tris-HCL buffer (pH 7.0). After centrifugation, the resulting pellets were reextracted with the same buffer and centrifuged. To the combined supernatant solution, solid ammonium sulfate was added to a final concentration of 70% saturation. The resulting precipitate was resuspended in 2 mM sodium phosphate buffer (pH 8.6) and dialyzate against the same buffer. The dialyzate was applied to a column of DEAE-cellulose (DE-52) and eluted with a linear gradient from 2 mM to 250 mM sodium phosphate. The enzyme active fractions were pooled, precipitated with ammonium sulfate and dialyzed. The dialyzate was applied to a column of Affi-Gel Blue (Bio Rad) and eluted with a linear gradient from 0 to 1M NaCl. The major active fractions were pooled and concentrated by ultrafiltration with a YM-10 membrane (Amicon). The concentrate was applied to a column of Sephacryl S-300 and eluted with 0.1M NaCl. The enzyme active fractions were pooled, concentrated with a YM-10 membrane and applied to a hydroxylapatite column and then eluted with a linear gradient from 10 mM to 400 mM potassium phospate. On this hydroxylapatite chromatography, two enzyme activities were separated (designated as AE-I and AE-II). The major active fraction (AE-I) was further purified by high-performance hydroxylapatite (HPHT) chromatograhy. Final purification was carried out by gel-filtration on a column of Seperose 12.

Although this enzyme was designated as AE-1 in the above-mentioned reference, it is designated as a native enzyme in the present invention.

(1) Determination of N-terminal Amino Acid Sequence of Native Enzyme

12 μg of the native enzyme was applied to a Protein Sequencer 470A (Applied Biosystems) for automatic Edman degradation, and as a result, the native enzyme was sequenced at the N-terminal thereof as Ser-Leu-Ser-Asn-Asp-X-Leu-Gly-Thr-Arg-Pro-Val-Met-Ser- (FIG. 5). Note, since X could not be detected as a phenylthiohydration derivative, it was predicted as a Cys residue.

(2) Determination of Amino Acid Sequences of Tryptic Fragments of Native Enzyme

40 μg of the native enzyme was dissolved in 20 μl of 50 mM Tris-HCl(pH 8.0)−2 mM CaCI₂, 0.5 μg of trypsin was added to the solution, and the reaction mixture was incubated at 37° C. for 2 hours. Then, 0.5 μg of trypsin was again added to the mixture, which was then incubated at 37° C. for 20 hours to hydrolyze the native enzyme. Next, the reaction mixture was subjected to high performance liquid chromatography (HPLC) using a Chemcosorb 3 ODS-H column (Chemco, 8.0×75 mm), and tryptic fragments produced by the trypsin treatment were eluted by a CH₃CN concentration linear gradient using 0.1% TFA and 0.1% TFA/60% CH₃CN to separate each fragment. Among these fragments, amino acid sequences of 14 tryptic fragments T-4, T-6, T-8, T-11, T-9, T-10, T-18, T-22, T-23, T-24, T-30, T-35, T-39, and T-45 were determined by the same procedure as described for the N-terminal sequencing of the native enzyme (FIG. 5).

(3) Amino Acid Composition of Native Enzyme

About 10 μg of the native enzyme was hydrolyzed with 6N hydrochloric acid at 110° C. for 24 hours, and the reaction mixture was analyzed using a Hitachi 835-50 type amino acid analyzer. The results are shown in Table 1.

Example 2 Preparation of Total RNA from Skin of Xenopus laevis

(1) Preparation of Whole RNA

Frog skins (wet weight 2 g) dissected out from Xenopus leavis were homogenized with a Polytron homogenizer in 10 ml of PC9 [phenol/chloroform/isoamyl alcohol=24:24:1, saturated with 10 mM Tris-HCL (pH 9.0), 0.1 MNaCl and 5 mMEDTA] and 10 mM of NETS solution [100 mM Tris-HCL (pH 9.0), 100 mM NaCl, 10 mM EDTA, 5% SDS]. Next, the homogenate was centrifuged at 3000 rpm for 30 minutes at a room temperature to obtain an aqueous solution, to which the same volume of CIAA (chloroform/isoamyl alcohol=49:1) was added, and the whole was mixed and centrifuged at 3000 rpm for 30 minutes at a room temperature. An aqueous phase was obtained and again treated with CIAA, and to the aqueous solution thus obtained was added two volumes of ethanol, and ethanol precipitation was carried out at −20° C. overnight. After centrifugation at 3000 rpm and 4° C. for 30 minutes, the supernatant was eliminated, and the precipitate was washed with 80% ethanol and dried under a vacuum. The precipitate was then dissolved in 2 ml of 4.2 M guanidine thiocyanate, 0.1 M sodium acetate, 5 mM EDTA (pH 5.0). To a SW40TI centrifugation tube 4 ml of 5 M CsCl, 0.1 M sodium acetate, 5 mM EDTA (pH 5.0) was added, the guanidine thiocyanate solution was overlaid, and the whole was centrifuged at 33,000 rpm and at 25° C. for 15 hours. After centrifugation, an RNA fraction was obtained in the bottom of the tube. The precipitate was washed with 80% ethanol, and dissolved in 500 μl of ETS solution (10 mM Tris-HCl, pH 7.5, 10 mM EDTA and 0.5% SDS). To the solution was added 400 μl of phenol saturated with 0.1 M Tris-HCl, pH 8.0, and after stirring, the whole was centrifuged at 10,000 rpm for 5 minutes. The aqueous phase was obtained, and the same volume of ethyl ether was added to the aqueous phase, and the whole was centrifuged at 3000 rpm for 1 minute to eliminate the ether layer. To the aqueous phase were added {fraction (1/10)} volume of 2 1 sodium acetate (pH 5.0), and two volumes of ethanol, and ethanol precipitation was carried out at −80° C. for 30 minutes. The mixture was centrifuged at 13,000 rpm and 4° C. for 10 minutes, and after eliminating the supernatant, the precipitate was washed with 80% ethanol. The precipitate was dried and dissolved in an appropriate volume of sterilized water. The above-mentioned procedure was repeated, and from 64 g of the skin of Xenopus laevis, 16.5 mg of total RNA was prepared.

(2) Preparation of Poly (A) RNA

0.5 g of oligo (dT) cellulose (Cellaborative Research Inc.) was filled in a column, and the column was washed with 10 ml of sterilized water, 10 ml of 0.1 M NaOH/5 mM EDTA, and then with sterile distilled water until a pH value of effluent from the column was lowered to less than 7.0. The column was equilibrated with 10 ml of 1×loading buffer (20 mM Tris-HCl, pH 7.6, 0.5 M NaCl, 1 mM EDTA, 0.1% SDS).

On the other hand, the whole RNA preparation prepared in Example 2. (l) was adjusted to a volume of 3 ml by adding sterilized water to make a whole RNA concentration of 3 μg/ml, and the whole was incubated at 65° C. for 5 minutes, and immediately put into water to cool to a room temperature. To the mixture was added 3 ml of 2×loading buffer (40 mM Tris-HCl, pH 7.6, 1.0 M NaCl, 2 mM EDTA, 0.2% SDS) to make a total volume of 6 ml.

This mixture was applied to the above-prepared oligo (dT) cellulose column. A flow-through fraction was again incubated at 65° C. for 5 minutes, and applied to the column. Then the column was washed with 4 ml of 1×loading buffer and 4 ml of 1×loading buffer (0.1 M NaCl), and poly (A) RNA was eluted with 4 ml of an elution buffer (10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 0.05% SDS). Ethanol precipitation was carried out by adding {fraction (1/10)} volume of 2 M sodium acetate and 2 volumes of ethanol to the elute fraction to recover poly (A) RNA, and from 9 mg of the total RNA, 74 μg of poly (A) RNA was obtained.

Example 3 Preparation of cDNA Library

(1) Preparation of cDNA

Double stranded cDNA was prepared from 7 μg of the poly (A) RNA derived from the skin of Xenopus laevis, prepared as described above, using a cDNA synthesis system kit (Amersham). To a final reaction mixture from the cDNA synthesis system kit were added 10 μl of 0.25 M EDTA (pH 8.0) and 10 μl of 10% SDS, followed by 120 μl of PC9, and after stirring, the mixture was centrifuged at 10,000 rpm and at a room temperature for 5 minutes to recover an aqueous layer. Ethanol precipitation was carried out by adding 120 μl of 4 M ammonium acetate and 480 μl of ethanol to 120 μl of the aqueous layer, and incubating the whole at −80° C. for 30 minutes. After centrifugation, the resulting ethanol precipitate was washed with 80% ethanol, dried in vacuum, and dissolved in 10 μl of sterilized water. To the solution, were added 2 μl of 10×cacodylate solution (1.4 M sodium cacodylate, 0.3 M Tris-HCl, pH 6.8), 2 μl of 1 mM dCTP, 2 μl of 1 mM DTT and 2 μl of 10 mM CoCl₂ as well as 10 units of terminal deoxitransferase (Pharmacia), and the reaction was carried out at 37° C. for 10 minutes. To the reaction mixture, were added 2 μl of 0.25 M EDTA (pH 8.0) and 1 μl of 10% SDS, followed by 23 μl of PC9, and after stirring, the whole was centrifuged at 13,000 rpm for 5 minutes to recover an aqueous layer. A PC9 layer was reextracted with 10 μl of 1×TE (100 mM Tris-HCl, pH 7.5, 1 mM EDTA). Ethanol precipitation was carried out by adding 32 μl of 4 M sodium acetate and 128 μl of ethanol to 32 μl of the above-obtained aqueous layer, and incubating the mixture at −80° C. for 30 minutes. After centrifugation at 13,000 rpm and at 4° C. for 15 minutes, and elimination of the upper layer, 50 μl of 1×TE was added to the ethanol precipitate to dissolve same. Ethanol precipitation was carried out by adding 50 μl of 4 M ammonium acetate and 200 μl of ethanol to the TE solution, and keeping the mixture at −80° C. overnight. After centrifugation at 13,000 rpm and at 4° C. for 15 minutes, the ethanol precipitate was washed with 80% ethanol, and after drying, dissolved in 40 μl of sterilized water. To this solution were added 120 μl of 5×annealing buffer (0.5 M NaCl, 50 mM Tris-HCl, pH 7.5, 1 mM EDTA), 0.6 μg of dG-tailed pBR322 (Bethesda Research Laboratories: dG-tailed pBR322, PstI cut), and 437 μl of sterilized water, and annealing with a pBR322 vector was carried out at 65° C. for 5 minutes, at 44° C. for 2 hours, and then in a water bath overnight.

(2) Transformation of E. coli DH1

A DH1 strain (F⁻, recA1, and A1, gyrA96, thi-1, hsdR17, supE44, relA13, λ⁻¹) derived from E. coli K12 was treated according to the RbCl method (Saibo Kopaku, 2, No. 3, p 97, 1983) to prepare competent cells. 20 μl of the annealing mixture prepared as described above was added to 200 μl of the competent cells, and the whole was allowed to stand in ice for 30 minutes, then incubated at 37° C. for 2 minutes, and immediately put into ice. To the transformation mixture was added 800 μl of o medium (Bacto Yeast Extract 5 g, Tryptone 20 g, MgSO₄ 5 g in 1 l, pH 7.6), and culturing was carried out at 37° C. for 60 minutes. After culturing, 1 ml of 80% glycelol was added to the culture, which was then frozen at −80° C. to store cultured cells. According to the above-mentioned procedure, an Xenopus laevis skin cDNA library consisting of 7.5×10⁵ clones was prepared.

Example 4 Isolation of cDNA Coding for C-terminal α-amidating Enzyme

(1) Preparation of DNA Probe

To isolate a cDNA coding for a C-terminal α-amidating enzyme from the cDNA library, mixed DNA probes designated as YS012, YS013, and YS015 corresponding to a partial amino acid sequence of the tryptic fragments T₃₀ and T₁₁ of the native enzyme were synthesized (see FIG. 6). Next, 1 pmole of each mixed DNA probe was treated with [−³²P] ATP and T₄ polynucleotide kinase to introduce [³²P] to 5′ hydroxyl of each DNA probe.

(2) Colony Hybridization

The cDNA library stored at −80° C. was thawed, and plated on a nutrient agar plate containing 5 μg/ml tetracycline, and cultured at 37° C. overnight. A nitrocellulose filter (Schleicher & Schuell) was put on the colonies and maintained for 5 minutes. The nitrocellulose filter was put on a fresh nutrient agar plate containing 5 μg/ml tetracycline in such a manner that the colonies on the filter were upward, and culturing was carried out at 37° C. for 8 hours. Next, this nitrocellulose filter was put on a different fresh nutrient agar plate containing 170 μg/ml chloramphenicol in such a manner that the colonies on the filter were upward, and incubated at 37° C. overnight. Next the nitrocellulose was put on an alkaline denaturation solution (0.1 M NaOH, 1.5 M NaCl) for 10 minutes, and then on a neutralizing solution (0.5 M Tris-HCl, pH 7.5, 1.5 M NaCl) for 10 minutes. After that, the nitrocellulose was rinsed with 2×SSC solution (20×SSC: NaCl 175.3 g, trisodium citrate 88.2 g in 1 l) and dried in air. The filter was heated at 80° C. for 120 minutes under a reduced pressure, and colony hybridization was carried out according to a method of W. I. Wood, Pro. Aatl. Acad. Sci. USA, 82, 1583-1588, 1985. Namely, the nitrocellulose filter was packed in a vinyl sack, and to the sack were added 5 ml of hybridization solution (3×SSC, 50 mM sodium phosphate, pH 6.8, 5×Denhart solution (1×Denhart solution: albumin, polyvinyl pyrrolidone, Ficoll, each 0.2 mg/ml), salmon sperm DNA 0.1 mg/ml), and prehybridization was carried out at 37° C. for 3 hours.

Next, a one million cpm/filter of the above-mentioned mixed DNA probe was added, and hybridization was carried out at 37° C. overnight. The filter was washed twice with 3×SSC at 4° C., and after an addition of a tetramethylammonium chloride solution (3.0 M tetramethylammonium, 50 mM Tris-HCl, pH 8.0, 2 mM EDTA, 0.1% SDS), further washed twice at 37° C. for 30 minutes and twice at 52° C. for 30 minutes. After air-drying, autoradiography was carried out at −80° C. overnight, and as a result, one clone which hybridized with the probe was obtained from the cDNA library consisting of about 400,000 clones.

This clone was designated as E. coli DH1/pXA457, and deposited with the Fermentation Research Institute Agency of Industrial Science and Technology (FRI), 1-3, Higashi 1-chome, Tsukuba-shi, Ibaraki-ken 305, Japan, as FERM BP-1367, on May 20, 1987.

Example 5 Analysis of Plasmid PXA457 and Determination of Nucleotide Sequence of cDNA

Plasmid pXA457 was isolated and purified from the above-mentioned E. coli DH1/pXA457 according to a conventional procedure. The plasmid pXA457 thus obtained was cleaved with various kinds of restriction enzymes, and a restriction enzyme cleavage map of cDNA which had been inserted into the PstI site of pBR322 was made. This map is shown in FIG. 7(a). The cDNA has a size of about 2.7 kb. Next, to determine a nucleotide sequence of the cDNA, various kinds of restriction fragments were cloned into M13 phage, and a dideoxy method of Sanger, F. et al Pro. Natl. Acad. Sci. USA, 34, 5463-5467 (1977) was carried out using a Takara DNA sequencing kit. The orientation for sequencing the cDNA is shown in FIG. 7(b). A nucleotide sequence of the cDNA in plasmid pXA457 and an amino acid sequence expected from the nucleotide sequence are shown in FIG. 1- to 1-4.

Example 6 Construction of XA Expression Vector ptrpXAST8 and XA Producing Strain E. coli W3110/ptrpXAST8

A protein coded by nucleotides 112 to 1200 of the cDNA in plasmid pXA457 is designated as “XA”, and an XA expression vector ptrpXAST8 and XA producing strain E. coli W3110/ptrpXAST8 were constructed as follows.

(1) Construction of pUC118XA (EcoRI) (FIG. 8)

A cDNA portion (PstI fragment) of pXA457 was cloned into the PstI site of M13mp19 (Takara Shuzo, Japan) to construct M13XA457. Next, the M13XA457 was subjected to in vitro mutagenesis using a synthetic DNA: 5′ GTC ATT GGA AAG TGA CAT GAA TTC TTC CTC ATA CCT CTT 3′ according to a method of Morinaga et al, Biotechnology 2, 636-639, 1984, to convert a nucleotide sequence; 5′ TCT ACC AGA 3′ of CDNA (nucleotides 103 to 112) to a nucleotide sequence 5′ GAA TTC ATG 3′, resulting in a construction of M13XA457 (EcoRI) wherein a restriction enzyme EcoRI site GAA TTC and a Met codon ATG have been introduced immediately upstream of nucleotides 112 to 114 coding for Ser at the amino acid position 1 in FIG. 1. Next, the M13XA457 (EcoRI) RF (replication form) was cleaved with EcoRI and PstI, and an EcoRI-PstI DNA fragment was cloned into EcoRI-PstI sites of pUC18 (Takara Shuzo, Japan) to construct pUC18XA (EcoRI).

(2) Construction of ptrpXAST4 (FIG. 9)

Plasmid ptrpGIFsα was cleaved with EcoRI and Sal I to obtain a DNA fragment containing a tryptophan operon (fragment A in FIG. 9). Note, E. coli WA802/ptrpGIFsα, which contains the plasmid ptrpGIFsaα, was deposited with the FRI as FERM P-8503 on Oct. 29, 1985, and transferred to international deposition under the Budapest treaty as FERM BP-1933 on Jul. 1, 1988.

On the other hand, the plasmid pUC18XA was cleaved with EcoRI and HhaI to obtain an EcoRI-HhaI DNA fragment (fragment B in FIG. 9).

Next, the fragment A, the fragment B, and a synthetic DNA linker:

   HhaI        Sal I 5′    CAG TGT GAG      3′ 3′ GCG TCA CAC TCA GCT 3′

were ligated together to construct a plasmid ptrpXAST4.

(3) Construction of Plasmid ptrpXASTB and E. coli W3110/ptrpXAST8 (FIG. 10)

The above-constructed plasmid ptrpXAST4 was cleaved with EcoRI and Sal I to obtain an EcoRI-Sal I DNA fragment (fragment C in FIG. 10). On the other hand, plasmid pT₄TNFST8rop⁻ was cleaved with Sal I and Bam I to obtain a Sal I-BamHI DNA fragment (fragment D in FIG. 10). Note, pT₄TNFST8rop⁻ was constructed from plasmid pBR322-PL-T4-hTNF according to the process described in Japanese Unexamined Patent Publication (KOKAI) No. 62-077324. The plasmid pBR322-PL-T4-hTNF was deposited with the Deutsche Sammlung von Mikroorganismen Gesellschaft fur Biotechnotogische Forschung mbH as DSM 3175. Moreover, ptrpGIFsα was cleaved with EcoRI and BamHI to obtain an EcoRI-BamHI DNA fragment (fragment T in FIG. 10). These fragments C, D and T were ligated using a T₄ DNA ligase and the ligation mixture was used to transform E. coli W3110. The transformants were screened to obtain an XA expression vector ptrpXAST8 and an XA producing strain E. coli W3100/ptrpXAST8.

Example 7 Construction of XDA Expression Vector ptrpXDAST8 and XDA Producing Strain E. coli W3110/ptrpXDAST8

A protein coded by nucleotides 112 to 1143 of the cDNA in plasmid pXA457 is designated as “XDA”. The XDA expression vector ptrpXDASTB and XDA producing strain E. coli W3110/ptrpXDAST8 were constructed as follows.

(1) Synthesis of DNA Linker (F) (FIG. 11)

To introduce a translation stop codon TGA and a Sal I site immediately downstream of nucleotides 1141 to 1143 coding for Lys in the cDNA, the following four DNA fragments (1) to (4) were synthesized.

(1) 5′ GTC ACC ACC ATA CAG AAG CTG AGC CTG AG 3′ (2) 5′ AAG AAT ACA GGA CTT CAG CAG CCT AAA TGA G 3′ (3) 5′ GTA TTC TTC TCA GGC TCA GCT TCT GTA TGG TG 3′ (4) 5′ TCG ACT CAT TTA GGC TGC TGA AGT CCT 3′

Next, the fragments (2) and (3) were phosphorylated at the 5′-ends thereof using ATP and T₄ polynucleotide kinase, and the DNA fragments (1) and (4) were added to the phosphorylated DNA fragments (2) and (3). The mixture was treated with T₄ DNA ligase to synthesize a double stranded DNA linker (F) wherein DNA fragments (1) and (2), and DNA fragments (3) and (4) were ligated.

(2) Construction of PtrpXDAST4 (FIG. 12)

The plasmid XAST4 was cleaved with BstE II and Sal I to obtain a BstE II-Sal I DNA fragment (fragment G in FIG. 12). This DNA fragment G was ligated with the above-synthesized DNA linker F using T₄ DNA ligase to obtain the title plasmid ptrpXDAST4.

(3) Construction of ptrpXDST8 and E. coli W3110/ptrpXDAST8 (FIG. 13)

The plasmid ptrpXDAST4 was cleaved with EcoRI and Sal I to obtain an EcoRI-Sal I DNA fragment (fragment H in FIG. 13). Plasmid pT₄TNFST8rop was cleaved with Sal I and BamHI to obtain Sal I-BamHI DNA fragment (fragment I in FIG. 13), and plasmid ptrpGIFsα was cleaved with EcoRI and BamHI to obtain an EcoRI-BamHI DNA fragment (fragment J in FIG. 13). Next, the fragments H, I, and J thus obtained were ligated with T₄DNA ligase, and the ligation mixture was used to transform E. coli W3110. The transformants were screened to obtain an XDA expression vector ptrpXDAST8

EXAMPLE 8 Expression of XA and XDA in E. coli

The XA producer strain E. coli W3100/ptrpXAST8, and the XDA producer strain E. coli W3100/ptrpXDAST8 were separately cultured in L-broth (polypepton 10 g, sodium chloride 5 g, yeast extract 5 g in 1 water) supplemented with 50 μg/ml ampicillin, overnight. This cultured broth was inoculated to 20 volumes of M9 medium (0.5% sodium monohydrogen phosphate, 0.3% potassium dihydrogen phosphate, 0.5% sodium chloride, 0.1% ammonium chloride) supplemented with 0.2% casamino acid, 5 μg/ml indoleacrylic acid (IAA) and 50 μg/ml ampicillin, and cultured at 37° C. for 7 hours. On the other hand, a control strain E. coli W3110 was cultured in a medium having the same composition as described above except that ampicillin was not contained therein. Next, each culture was centrifuged to collect cells, and the total protein of the cells was determined by SDS-PAGE according to a method of Laemmli, L. K. et al, Nature 227, 680-685, 1970. The results are shown in FIG. 14(a).

E. coli W3110/ptrpXAST8 and E. coli W3110/ptrpXDAST8 produced, in comparison with the control strain E. coli W3110, a specific protein XA having a molecular weight of about 40K and a specific protein XDA having a molecular weight of about 38K, respectively. When cells were suspended in PBS(−) (0.8% sodium chloride, 0.02% potassium chloride, 0.15% sodium monohydrogen phosphate, 0.02% potassium dihydrogen phosphate), disrupted by ultrasonication, and the sonicate was centrifuged at 10,000 rpm for one minutes, a major portion of the protein XA and XDA was transferred to the precipitate.

Example 9 Comparison of Properties of XA, XDA and Native Protein

(1) Comparison of Molecular Weight

Cells of E. coli W3100/ptrpXAST8 and cells of E. coli W3100/ptrpXDAST8 cultured by the same procedure as described in Example 8 were collected, resuspended in PBS(−), and disrupted by ultrasonication, and the sonicate was centrifuged at 10,000 rpm for one minute to obtain a precipitation fraction. By this procedure, a major portion of XA and XDA was transferred to the precipitation fraction, and many proteins derived from the host E. coli W3110 were transferred to a supernatant. The molecular weights of the XA protein and XDA protein enriched as described above, as well as that.of the native enzyme, were compared by SDS-PAGE. The molecular weight of the XDA was exactly the same as that of the native enzyme. The results are shown in FIG. 14(b).

(2) Comparison of Amino Acid Composition

Each XA and XDA enriched as described above was separated from impurifies by SDS-PAGE, a gel piece-containing band corresponding to XA or XDA was excised, and the protein XA or XDA was extracted with TES (10 mM Tris-HCl, pH7.0, 1 mM EDTA, 0.1 M NaCl) from the gel piece. The extract was dried, and dissolved in 0.1% SDS. The solution was then dialyzed in 0.1% SDS overnight. The dialyzate was once dried and redissolved in a small amount of water. Methanol was added to the solution to precipitate XA or XDA, which was then used for amino acid analysis. The amino acid analysis was carried out by hydrolyzing 10 μg of the sample with 6N hydrochloride at 110° C. for 72 hours, and analyzing the hydrolyzate with a Hitachi 853-50 type amino acid analyzer. The results are shown in Table 1.

TABLE 1 Amino Native acid Enzyme XDA XA Trp ND ND ND CySO₃H ND ND ND Asp 32.4 32.8 34.2 Thr 24.4 21.1 21.7 Ser 22.3 19.2 19.1 Glu 27.3 27.1 31.8 Pro 32.0 28.5 28.5 Gly 27.2 31.6 32.4 Ala 20.0 20.4 21.2 Cys ND ND ND Val 24.0 24.5 26.3 Met 14.9 15.0 15.1 Ile 15.7 16.0 17.0 Leu 18.2 18.0 20.8 Tyr 16.7 16.0 15.7 Phe 10 10 10 Lys 15.3 13.5 13.6 His 13.5 14.6 14.8 Arg 14.2 13.9 14.8 ND: not detected

In Table 1, when a comparison is made between the amino acid compositions of the native enzyme, XA and XDA, presuming that the number of phenylalanine residues in the native enzyme, XA and XDA is 10, the numbers of aspartic acid residue, glutamic acid residue, valine residue, isoleucine residue, leucine residue and arginine residue are not different in the native enzyme and the XDA, it appears that the XDA is the same as the native enzyme. Since both the XDA and XA exhibit a C-terminal α-amidating activity, it is considered that the C-terminal region (at least Arp (345) to Val (363) of the protein (prepro-enzyme) translated from the cDNA is not essential for enzyme activity. Accordingly, it is thought that, during biosynthesis of the C-terminal α-amidating enzyme of the skin of Xenopus laevis, first a prepro-enzyme consisting of 400 amino acids is expressed, and the prepro-enzyme is cleaved at a peptide bond between Arg (−1)-Ser (+1) to excise N-terminal region and at a peptide bond probably between Lys (344)-Arg (345) to excise the C-terminal region, resulting in the native enzyme.

Example 10 C-terminal α-amidating Activity of XA and XDA

E. coli W3100/ptrpXAST8 and E. coli W3100/ptrpXDAST8, and a control strain E. coli W3100, were cultured as described above, and 20 ml each of the cultured broth was centrifuged to collect cells, which were then resuspended in 200 μl of PBS(−) and the suspension treated by ultrasonication to disrupt the cells. Next, the disruptant was centrifuged to recover the precipitated, which was then solubilized with 250 μl of 6M guanidine hydrochloride. This solution was successively dialyzed in 200 ml of 4M guanidine hydrochloride containing 10 mM Tris-HCL (pH 7.0) and 50 μm CuSO₄ for one hour, in 200 ml of 2M guanidine hydrochloride containing 10 mM Tris-HCL (pH 7.0) and 50 μm CuSO₄ for one hour, and then in 200 ml of 10 mM Tris-HCL (pH 7.0) containing 50 μm CuSO₄ for one hour. The dialyzate thus obtained was centrifuged to obtain a supernatant, which was then used for an assay of the enzyme activity.

The assay was carried out according to a method of Mizuno et al, B.B.R.C. 137, 984-991, 1986, as follows. Namely, 12.5 μl, 25 μl, and 50 μl of the sample prepared as described above were diluted to a total volume of 100 μl by adding distilled water. To the above-prepared solution were added 25 μl of 10 mM N-ethylmaleimide, 25 ml of 10 mM ascorbic acid, 25 μl of 200 μM CuSO₄ 1.25 μl of 20 mg/ml catalase, 25 μl of 1% Lubrol, 2 pmoles (170,000 cpm) of [¹²⁵I]-Ac-Tyr-Phe-Gly, and 50 μl of 1M Tris-HCl (pH 7.0), and the mixture was allowed to react at 37° C. for 15 hours. After the reaction, 750 μl of 1M Tris-HCl (pH 7.0) and 2 ml of ethyl acetate were added to the reaction mixture, and the whole was mixed and centrifuged. Next, 1 ml of ethyl acetate layer was removed, and the radioactivity of both the ethyl acetate layer and the residual solution was measured by a γ-counter, and a ratio of radioactivity transferred to the ethyl acetate layer was obtained. Note, it has been confirmed by liquid chromatography and a γ-counter that a C-terminal α-amidated product [¹²⁵I]-Ac-Tyr-Phe-NH₂ is specifically transferred to the ethyl acetate layer.

The results are shown in FIG. 15. Although the product from E. coli W3110 did not exhibit an enzyme activity, the activity of the products XA and XDA increased in parallel with an increase of the supernatant added, revealing that a C-terminal α-amidating enzyme was actually produced.

The XA was produced in an amount of 15 mU/ml culture broth, and the XDA was produced in an amount of 11 mU/ml of culture broth.

Example 11 Isolation of cDNA Coding for Different C-terminal α-amidating Enzyme (2)

(1) Preparation of DNA Probe

To prepare a probe for isolation of a cDNA coding for a different C-terminal α-amidating enzyme from a cDNA library derived from the skin of Xenopus laevis, the plasmid pXA457 was completely digested with PvuII to isolate a DNA fragment of about 0.74 kb corresponding to nucleotide 54 to 795 of the cDNA in pXA457, as shown in FIGS. 1-1 to 1-3. The fragment was designated as a PvuII DNA fragment.

Next, the PvuII DNA was radio-labeled with [α-³²P] CTP by nick-translation.

(2) Colony Hybridization

A cDNA library prepared according to the same procedure as described in Examples 2 and 3, and stored at −80° C., was thawed and plated onto a nutrient agar plate supplemented with 5 μg/ml tetracycline, and cultured at 37° C. overnight. A nitrocellulose filter (Schleicher & Schuell) was placed on the colonies and maintained for 5 minutes. The nitrocellulose filter was placed on a fresh nutrient agar plate containing 5 μg/ml tetracycline in such a manner that the colonies on the filter were upward, and culturing was carried out at 37° C. for 8 hours. Next, this nitrocellulose filter was placed on a different fresh nutrient agar plate containing 170 μg/ml chloramphenicol in such a manner that the colonies on the filter were upward, and incubated at 37° C. overnight. Next the nitrocellulose was placed on an alkaline denaturation solution (0.1 M NaOH, 1.5 M NaCl) for 10 minutes, and then on a neutralizing solution (0.5 M Tris-HCl, pH 7.5, 1.5 M NaCl) for 10 minutes. After that, the nitrocellulose was rinsed with 2×SSC solution (20×SSC: NaCl 175.3 g, trisodium citrate 88.2 g in 1 l) and dried in air. The filter was heated at 80° C. for 120 minutes under a reduced pressure.

Using the nitrocellulose filters thus prepared, colony hybridization was carried out according to the following condition. Namely, two nitrocellulose filters were packed in a vinyl sack, and to the sack were added 5 ml of hybridization solution (3×SSC, 50 mM sodium phosphate, pH 6.8, 5×Denhart solution (1×Denhart solution: albumin, polyvinyl pyrrolidone, Ficoll, each 0.2 mg/ml), salmon sperm DNA 0.1 mg/ml); and prehybridization was carried out at 37° C. for 3 hours.

Next, 560,000 cpm/2 filters of the above-mentioned PvuII DNA probe and 0.5 ml of the above-mentioned prehybridization solution were added, and hybridization was carried out at 37° C. overnight. The filter was washed twice with 3×SSC containing 0.1% SDS at 37° C. for 30 minutes, and further washed twice with 0.1×SSC containing 0.1% SDS at 50° C. for 30 minutes. After air-drying, autoradiography was carried out at −80° C. overnight, and as a result, three clones which hybridized with the PvuII DNA probe were obtained from the cDNA library consisting of about 200,000 clones. These clones were designated as E. coli DH1/pXA747, E. coli DH1/pXA750, and E. coli DH1/pXA799, respectively. Among them E. coli DH1/pXA799 was found to contain a cDNA coding for a different C-terminal α-amidating enzyme.

This clone E. coli DH1/pXA799 was deposited with the Fermentation Research Institute Agency of Industrial Science and Technology (FRI), 1-3, Higahi 1 chome Tsukuba-shi Ibaraki-ken 305, Japan, as FERM BP-1586 on Dec. 3, 1987.

Example 12 Analysis of Plasmid PXA747, pXA750 and pXA799 and Determination of Nucleotide Sequence of cDNA in pXA799

Plasmids pXA747, pXA750, and pXA799 were prepared from E. coli DH1/pXA747, E. coli DH/pXA750, and E. coli DH1/pXA799, respectively, according to a conventional procedure. These plasmids were cleaved with restriction enzymes PstI, KpmI, HincII, PvuII, AccI, and EroR V, and as a result, since the restriction enzyme cleavage maps of plasmids pXA747 and pXA750 were roughly the same as that of pXA457, they were expected to contain the same cDNA as contained in pXA457. But, to the contrary, pXA799 contained the cDNA of about 3.4 kb, and the restriction enzyme cleavage map of pXA799 was clearly different from that of pXA457 (FIG. 17). This result suggests that the cDNA in pXA799 is different from that in pXA457, and therefore, the cDNA in pXA799 codes for a new type of C-terminal α-amidating enzyme different from the enzyme coded by the cDNA in pXA457.

Accordingly, the present inventors determined a nucleotide sequence of cDNA in pXA799 as described below. First, the cDNA in pXA799 was cleaved with various kinds of restriction enzymes, and the generated DNA fragments were subcloned into M13 phage. Next, the nucleotide sequence of each DNA fragment was determined using a Takara DNA sequencing kit (Takara Shuzo, Japan) according to the dideoxy method of Sanger, F. et al, Proc. Natl. Acad, Sci, USA, 34, 5463-5467 (1977). The results are shown in FIGS. 16-1 to 16-3. FIG. 18 shows the orientation of a sequencing of DNA fragments used for a determination of nucleotide sequences.

Example 13 Construction of Plasmids and Transformant for Expression of Protein Coded by cDNA in pXA799 and Derivatives Thereof

(1) Construction of pXA799(EcoRI) (FIG. 21)

Plasmid pXA799(EcoRI) is an expression plasmid which expresses a protein having an amino acid sequence from Ser(1) to Ser(836) is FIGS. 16-1 to 16-3. The plasmid pXA799 was subjected to in vitro mutagenesis using a synthetic DNA: 5′ GTC ATT GGA AAG TGA CAT GAA TTC TTC CTC ATA CCT CTT 3′ according to a method of Morinaga et al., Biotechnology 2, 636-639, 1984, to convert a nucleotide sequence 5′ TCA ACC AGA 3′ corresponding to nucleotides 109 to 117 in FIG. 16-1 to a nucleotide sequence 5′ GAA TTC ATG 3′, resulting in a plasmid pXA799 (EcoRI) which contains an EcoRI site (GAA TTC) and a translation start codon coding for Met (ATG) immediately upstream of a codon for Ser (1).

(2) Construction of pUCP_(L)CI (FIG. 22)

The plasmid pUCP_(L)CI is used to express a gene of interest under the control of a P_(L) promotor derived from_phage. Namely, by inserting a gene of interest having an EcoRI site and a translation start codon ATG at the 5′ terminal thereof into an EcoRI site in a polylinker region positioned downstream of a P_(L) promotor in the plasmid pUCP_(L)CI, the gene can be directly expressed in E. coli. Moreover, since the plasmid pUCP_(L)CI contains translation step codons provided by a synthetic DNA linker, a gene of interest having no translation stop codon can be expressed.

Three μg of the plasmid pUC-P_(L)-trpa disclosed in Japanese Patent Application No. 62-166710 was cleaved with 20 units of SphI, and then partially cleaved with 1 unit of HindIII to obtain a SphI-HindIII fragment (fragment E in FIG. 22).

Next, the E fragment was ligated with a synthetic DNA linker:

using a T₄ DNA ligase, to construct the plasmid pUCP_(L)CI.

(3) Construction of Plasmid UCP_(L)CI799Dra I and Transformant E. coli W3110/pUCP_(L)CI799 Dra I (FIG. 23)

The plasmid pUCP_(L)CI799Dra I and transformant E. coli W3110/pUCP_(L)CI799Dra I were constructed to express in E. coli cells a protein having a primary amino acid sequence of amino acids 1 to 836 in FIG. 16-1 to 16-3. Three μg of pUCP_(L)CI was cleaved with 20 units of EcoRI and 20 units of SmaI to isolate an EcoRI-SmaI fragment (fragment F in FIG. 23). Next, 3 μg of pXA799 (EcoRI) was cleaved with 20 units of EcoRI and 20 units of Dra I to isolated on EcoRI-Dra I fragment (fragment G in FIG. 23). These fragments F and G were ligated using a T₄ DNA ligase, and introduced to E. coli W3110 to construct a transformant E. coli W3110/pUCP_(L)CI799Dra I, from which a plasmid pUCP_(L)CI⁷99Dra I was isolated.

(4) Construction of Plasmid pUCP_(L)CI⁷⁹⁹Bgl II and Transformant E. coli W3110/pUCP_(L)CI 799 Bgl II (FIG. 24)

A plasmid PUCPLCI799Bgl II and transformant E. coli W3110/pUCP_(L)CI799Bgl II were constructed to express in E. coli a protein having an amino acid sequence of amino acids 1 to 692 in FIG. 16-1 to 16-3, and an additional Leu residue at a C-terminal derived from a starting plasmid PUCP_(L)CI. This protein is designated as 799Bgl II. Three pg of PUCP_(L)CI was cleaved with 20 units of EcoRI and 20 units of BamHI to isolate an EcoRI-BramHI fragment (fragment H in FIG. 24). On the other hand, 3 μg of pXA799(EcoRI) was cleaved with 20 units of EcoRI and 20 units of Bgl II to isolate an EcoRI-Bgl II fragment (fragment I in FIG. 24). Next, these fragments H and I were ligated using a T₄ DNA ligase and introduced to E. coli W3110 to construct a transformant E. coli W3110/pUCP_(L)CI799Bgl II, from which a plasmid pUCP_(L)C799Bgl II was isolated.

(5) Construction of plasmid PUCP_(L)CI799R V and Transformant E. coli W3110/pUCP_(L)CI799R V (FIG. 25)

A plasmid pUCP_(L)CI799R V and transformant E. coli W3110/pUCP_(L)CI 799R V were constructed to express in E. coli a protein having an amino acid sequence of amino acids 1 to 551 in FIG. 16-1 to 16-2 at the N-terminal side thereof, and an additional Met-Gly-Ile-Leu at the C-terminal thereof derived from a starting plasmid pLCP_(L)CI. This protein is designated as 799R V.

Three μg of PUCP_(L)CI was cleaved with 20 units of EcoRI and 20 units of Sma I to isolate an EcoRI-Sma I fragment (fragment J in FIG. 25). On the other hand, 3 μg of pXA799 (EcoRI) was cleaved with 20 units of EcoRI and partially cleaved with 1 unit of EcoR V to obtain an EcoRI-EcoR V fragment (fragment K in FIG. 25). Next, these fragments J and K were ligated using a T₄ DNA ligase and introduced to E. coli W3110 to construct a transformant E. coli W3110/pUCP_(L)CI799R V, from which a plasmid pUCP_(L)CI799R V was isolated.

(6) Construction of Plasmid pUCP_(L)CI799Sal I and Transformant E. coli W3110/pUCP_(L)CI799 Sal I (FIG. 26)

A plasmid PUCPLCI799Sal I and transformant E. coli W3110/pUCP_(L)CI799 were constructed to express in E. coli a protein having a primary amino acid sequence of amino acids 1 to 499 in FIG. 16-1 to 16-2 at the N-terminal side thereof and an additional Leu-Gln-Alα-Gys-Leu-Ile-Asn at the C-terminal thereof derived from a starting plasmid. This protein is designated as 799Sal I.

Three μg of pUCP_(L)CI799Bgl II was cleaved with 20 units of Sal I to isolate a larger DNA fragment (fragment L in FIG. 26), which was then intramolecularly ligated using T₄ DNA ligase and introduced to E. coli W3100 to construct a transformant E. coli W3100/pUCP_(L)CI799Sal I, from which a plasmid pUCP_(L)CI799Sal I was isolated.

(7) Construction of Plasmid pUC_(L)CI799Bst II^(L) and Transformant E. coli W3110/pUC_(L)CI799BstE II^(L) (FIG. 27)

A plasmid pUCP_(L)CI799BstE II^(L) and transformant E. coli W3110/pUCP_(L)CI799BstE II^(L) were constructed to express in E. coli a protein having a primary amino acid sequence of amino acids 1 to 329 in FIG. 16-1 to 16-2 at the N-terminal side thereof and an additional Gly-Asp-Pro-Leu-Glu-Ser-Thr-Cys-Arg-His-Ala derived from a starting plasmid pUCP_(L)CI at the C-terminal thereof. This protein is designated as 799BstE II^(L).

Three μg of pUCP_(L)CI was cleaved with 20 units of EcoRI and 20 units of SmaI to isolate an EcoRI-SmaI fragment (fragment M in FIG. 27). On the other hand, 3 μg of pXA799(EcoRI) was partially cleaved with 1 unit of BstE II, and after a fill-in of resulting cohesive ends using a T4 DNA polymerase and dNTP, again cleaved with 20 units of EcoRI to isolate an EcoRI-BstE II^(L) fragment (fragment N in FIG. 27). Next, these fragments M and N were ligated using a T₄ DNA ligase and introduced to E. coli W3110 to construct a transformant E. coli W3100/pUCP_(L)CI799BstE II^(L), from which a plasmid pUCP_(L)CI799BstE II^(L) was isolated.

(8) Construction of Plasmid pUCP_(L)CI799BstE II^(S) and Transformant E. coli W3100/pUCP_(L)CI799BstE II^(S)

A plasmid pUCP_(L)CI799BstE II^(S) and transformant E. coli W3100/pUCP_(L)CI799BstE II^(S) were constructed to express in E. coli a protein having a primary amino acid sequence of amino acids 1 to 298 in FIG. 16-1 at the N-terminal side thereof and an additional Gly-Asp-Pro-Leu-Glu-Ser-Thr-Cys-Arg-His-Ala derived from a starting plasmid PUCPLCI at the C-terminal thereof. This protein is designated as 799BstE II^(S).

Three μg of pUCP_(L)CI was cleaved with 20 units of EcoRI and 20 units of SmaI to isolate an EcoRI-SmaI fragment (fragment O in FIG. 28). On the other hand, 3 μg of pXA799 (EcoRI) was partially cleaved with 20 units of BstE II, and after a fill-in of resulting cohesive ends using T₄ DNA polymerase and dNTP, again cleaved with 20 units of EcoRI to isolate an EcoRI-BstE II^(S) fragment (fragment P in FIG. 28). Next, these fragments O and P were ligated using a T₄ DNA ligase and introduce to E. coli W3110 to construct a transformant E. coli pUCP_(L)CI799BstE II^(S), from which a plasmid pUCP_(L)CI799BstE II^(S) was isolated.

(9) Construction of Plasmid pXA799 (EcoRI-Sal I (FIG. 29)

A plasmid pXA799 (EcoRI-Sal I) was constructed to express in E. coli a protein having an amino acid sequence of amino acids 1 to 346 in FIG. 16-1 to 16-2.

The plasmid pXA799 (EcoRI) was subjected to in vitro mutagenesis using a synthetic DNA: 5′ CAG CAG CCT AAA TAG GTC GAC GAA GAA GTA TTA AAT 3′ to convert a nucleotide sequence 5′ CGG GAG GAG 3′ corresponding to nucleotides 1156 to 1164 of the cDNA in pXA799 shown in FIG. 16 to a nucleotide sequence 5′ TAG GTC GAC 3′, resulting in the construction of a plasmid pXA799(EcoRI-Sal I) wherein a translation stop codon TAG and a restriction enzyme Sal I site (GTC GAC) were introduced immediately downstream of the Lys coded by nucleotide 1153 to 1155 of the cDNA.

(10) Construction of Plasmid ptrp Δ799 and Transformant E. coli W3110/ptrp Δ799 (FIG. 30)

A plasmid ptrp 799 and transformant E. coli W3110/ptrpΔ799 were constructed to express, under the control of a tryptophan promoter, in E. coli a protein having a primary amino acid sequence of amino acids 1 to 346 in FIG. 16-1 to 16-2.

The plasmid ptrpGIFsα described in Example 6(2), which was designed to express a chimera protein of human interferon and α-neo-endorfin under the control of a tryptophan operon, was cleaved with EcoRI and Sal I to isolate a DNA fragment containing tryptophan operon (fragment A in FIG. 30). On the other hand, the pXA799 (EcoRI-Sal I) was cleaved with EcoRI and Sal I to isolate an EcoRI-Sal I DNA fragment (fragment B in FIG. 30). Next, these fragments A and B were ligated using a T₄ DNA ligase and introduced to E. coli W3110 to construct a transformant E. coli W3110/ptrpΔ799, from which a plasmid ptrp Δ799 was isolated.

(11) Construction of Plasmid ptrp799-457 and Transformant E. coli W3110/ptrp799-457Δ (FIG. 31)

A plasmid ptrp799-457Δ and transformant E. coli W3110/ptrp799-457Δ were constructed to express in E. coli a protein having a primary amino acid sequence consisting of amino acids 1 to 329 coded by cDNA in pXA799 at the N-terminal thereof and amino acids 365 to 381 coded by the cDNA in pXA457. This protein is designated as 799-457Δ.

Three μg of ptrpXDAST4 was cleaved with 20 units of EcoRI and 20 units of BstE II to isolate an EcoRI-BstE II fragment (fragment C in FIG. 31). On the other hand, pXA799(EcoRI) was cleaved with 20 units of EcoRI and then partially cleaved with 1 unit of BstE II to isolate an EcoRI-BstE II fragment (fragment D in FIG. 31). Next, these fragments C and D were ligated using a T₄ DNA ligase and introduced to E. coli W3110 to construct a transformant E. coli W3110/ptrp799-457Δ, from which a plasmid ptrp799-457Δ, from which a plasmid ptrp799-457Δ was isolated.

Example 14 Expression of Protein Coded by cDNA Derived from pXA799 and Derivative Thereof

Various kinds of E. coli transformants prepared as described in Example 13 were separately cultured to express coded proteins according to the following procedures.

(1) Expression of 799Dra I in E. coli

E. coli W3110/pUCP_(L)I799Dra I was cultured in a super broth (prepared by diluting 24 g of yeast extract, 12 g of trypton, 5 ml of glycerol and 100 ml of phosphate buffer (pH 7.6) with water to a total volume of 1 l) supplemented with 50 μg/ml ampicillin at 32° C. overnight. Next, E. coli cells thus cultured were inoculated to a super broth supplemented with 50 μg/ml ampicillin at a cell concentration of 0.01 OD/ml at 660 nm, and cultured until the cell concentration reached 0.3 OD/ml at 660 nm. At this point the culture temperature was shifted to 42° C., and cultivation was further continued until the cell concentration reached 2.0 OD/ml at 660 nm.

Note, other transformants prepared in Example 13, i.e., E. coli W3110/pUCP_(L)CI799Bgl II, E. coli W3110/pUCP_(L)CI799R V, E. coli W3100/pUCP_(L)CI799Sal I, E. coli W3110/pUCP_(L)CI799BstE II^(L), and E. coli W3110/pUCP_(L)CI799BstE II^(S), were cultured according to the same procedure as described for E. coli W3110/pUCP_(L)CI799Dra I.

(2) Expression of Δ799 in E. coli

E. coli W3110/ptrpA799 was cultured in a super broth supplemented with 50 μg/ml ampicillin at 37° C. overnight. Next, this cultured broth was inoculated to 20 volumes of M9 medium (0.5% sodium monohydrogen phosphate, 0.3% potassium dihydrogen phosphate, 0.5% sodium chloride, and 0.1% ammonium chloride) supplemented with 0.2% casamino acid, 5 μg/ml indoleacrylic acid, and 50 μg/ml ampicillin, and cultured at 37° C. for 7 hours.

Note, E. coli W3110/ptrp799-457Δ was also cultured according to the same procedure as described above.

(3) Determination of Product

The cultured broth prepared as above was centrifuged to collect cells, the whole protein of which was then analyzed according to a method of Laemmli, U.K., Nature 227, 680-685, 1970, by SDS-PAGE to detect the expressed target protein. Note, when cells were suspended in PBS(−) (0.8% sodium chloride, 0.02% potassium chloride, 0.15% sodium monohydrogen phosphate, and 0.02% potassium dihydrogen phosphate) and the suspension was treated with ultrasonication to disrupt cells and centrifuged, a major portion of the expressed proteins was recovered in a precipitate.

Example 15 Assay of C-terminal α-amidating Enzyme

10.0 OD (at 660 nm) of cells cultured in Example 14 were suspended in 200 μl of PBS(−) containing 0.1% Triton, and the suspension was treated by ultrasonication to disrupt the cells. Next, the disruption was centrifuged to recover a precipitated fraction, and the precipitate was then solubilized with 500 μl at 6 M guanidine hydrochloride. The solution thus prepared was then successively dialyzed in 200 ml of 4 M guanidine hydrochloride containing 10 mM Tris-HCl (pH 7.0) and 50 μM CuSO₄ for one hour, and then in 200 ml of 2 M guanidine hydrochloride containing 10 mM Tris-HCl (pH 7.0) and 50 μM CuSO₄, to prepare a sample for an assay of the enzyme activity.

Table 2 shows the activities of each of the proteins assayed. Note, a value of the enzyme activity of XA determined in Example 10 is shown for reference.

TABLE 2 Activity Derivatives units/cell OD600 = 1 XA 1.50 799Dra I 0.06 799Bgl II 0.06 799 RV 0.06 799Sal I 0.06 Δ799 0.80 799-457Δ 0.80 799 BstE II^(L) 0.10 799 BStE II^(S) 0

As seen from Table 2:

(1) Protein coded by the cDNA in pXA799 exhibits a C-terminal α-amidating enzyme.

(2) Not all of the amino acid sequence of protein 799Dra I is necessary for enzyme activity. Particularly, a C-terminal part of 799Dra I is not important. Actually, protein derivatives which lack the C-terminal part of 799Dra I, such as 799Bgl II, 799R V, 799Sal I, Δ799, 799-457Δ, and 799BstE II^(L), exhibited a C-terminal α-amidating activity.

(3) But, since 799BstE II^(S) does not exhibit an enzyme activity, a primary amino acid sequence of at least amino acids 1 to 329 coded by the cDNA derived from pXA799 is necessary for a C-terminal α-amidating activity.

Note, the enzyme activities of various derivatives shown in Table 2 are values of per unit cell mass (OD 660=1). Therefore the values do not denote the specific activity per protein.

Reference Example 1 Construction of Plasmid pT4TNFST8rop⁻ from Plasmid pBR322-PL-T4-hTNF Construction of Plasmids pPLT4TNF and pPLT4TNF-SalI

Five micrograms of plasmid pBR322-PL-T4-hTNF the E. coli strain C600/CI transformed with this plasmid has been deposited with the Culture Collection of the Deutsche Sammlung von Mikroorganismen, Göttingen, West, Germany, under Accession Number DSM3175 was completely digested with the restriction enzyme ClaI and digested partially with AvaI (0.5 unit). Half a microgram of a chemically synthesized ClaI-AvaI linker DNA fragment having the base sequence:

CGATACTACTATGGTCAGATCATCTTCTCGAACC   TATGATGATACCAGTCTAGTAGAAGAGCTTGGGGCT (ClaI)                         (AvaI)

was mixed in a ligation buffer and ligated with the previously obtained DNA fragment using 2 units of a T4DNA ligase. The solution was used to transform the E. coli strain W3110/CI, and from the transformants that were ampicillin-resistant and had the TNF producing capability, the desired plasmid pPLT4TNF was isolated by routine procedures.

Subsequently, a SalI cleavage site was inserted at a point immediately downstream of the TNF structural gene on the plasmid pPLT4TNF in accordance with the method of Morinaga, Y. et al. described in Biotechnology 2: 636-639, 1984. First, the pPLT4TNF was divided into two portions. One of them was completely cleaves with EcoRI and PstI to obtain a double-stranded DNA fragment that was deficient of the PL promotor containing DNA fragment. The other portion was cleaved with HindIII and BstEII to obtain a double-stranded DNA fragment that was deficient of a fragment containing part of the TNF gene at its 3′ end. The two DNA fragments (III) and (IV) were mixed with AB180 that was a chemically synthesized single-stranded DNA having a SalI cleavage site and the base sequence:

5′-ATCATTGCCCTGTGAGTCGACCGAACATCCAACCTT-3′. By heating at 100° C., the double-stranded DNA was changed to single-stranded DNA, which then was slowly cooled to form a double-stranded chain by annealing. To the reaction solution, dNTPs and DNA polymerase (Klenow fragment), as well as T4DNA ligase and ATP were added and reaction was carried out to form a closed circular double-stranded DNA. The resulting solution was used to transform the E. coli strain W3110/CI and ampicillin-resistant transformants were selected. Plasmid was isolated from the transformants and restriction enzyme analysis revealed that it was the desired plasmid pPLT4TNF-SalI which contained a SalI cleavage site immediately downstream of the TNF structural gene.

Construction of Plasmid pPLT4TNFST8

The plasmid pPLT4TNF-SalI constructed in Reference Example 1 was subjected to the following procedures in order to construct the plasmid pPLT4TNFST8 wherein the terminator trp a was inserted at a point immediately downstream of the codon for terminating the translation of the TNF structural gene on pPLT4TNF-SalI and whose drug resistance marker was tetracycline, rather than ampicillin.

A fragment (1) was obtained by cleaving pPLT4TNF-SaII with AhaIII and SalI and which harbored the PLT4 promoter and the TNF gene. Using a T4DNA ligase, this fragment was ligated with a chemically synthesized DNA segment (2) and an EcoRI-AhaIII DNA fragment (3) in a three-fragment ligation. Segment (2) ended with a SalI cohesive site and an EcoRI cohesive site and had the following base sequence (terminator trp a: trp a):

TCGACAGCCCGCCTAATGAGCGGGCTTTTTTTTCTCGG     GTCGGGCGGATTACTCGCCCGAAAAAAAAGAGCCTTAA   SalI                                  EcoRI.

Fragment (3) was a large (3.2 kb) fragment that contained the tetracycline resistance gene Tc^(r) and which was obtained by cleaving the plasmid pBR322 with AhaIII and EcoRI. The ligation product was used to transform the E. coli strains W3110/CI and WA802/CI. The transformants were tetracycline-resistant and screened for ampicillin sensitivity. Plasmid was isolated from each of the transformants by routine procedures and restriction enzyme analysis verified the construction of the desired plasmid pPLT4TNFST8.

The E. coli strain WA802/CI/pPLT4TNFST8 obtained by transformation with the plasmid pPLT4TNFST8 was named SBM 281 and has been deposited with the Fermentation Research Institute, the Agency of Industrial Science and Technology, under Deposit Number FERM BP-906.

Construction of Plasmid DT4TNFST8

Five micrograms of the plasmid pPLT4TNFST8 obtained in Reference Example 2 was partially digested with EcoRI (0.5 unit) and the EcoRI cohesive end was made blunt (filled in) with a DNA polymerase in the presence of dNTPs (i.e., DATP, dGTP, dTTP and dCTP). Subsequently, the pPLT4TNFST8 was cleaved at the AhaIII site by addition of 5 units of AhaIII and ligation was conducted with a T4DNA ligase. The resulting ligation solution was used to transform the E. coli strains WA802 and W3110. Plasmid DNA was isolated from the tetracycline-resistant transformants (which were named WA802/pT4TNFSTB and W3110/pT4TNFST8) and restriction enzyme analysis revealed that these transformants had the desired plasmid pT4TNFST8.

Construction of Plasmid pT4TNFST8rop⁻

The plasmid pT4TNFST8rop⁻ which lacked the pBR322-derived rop (repressor of primer) gene on pPLT4TNFST8 having the function of controlling plasmid DNA replication was constructed by the following procedures.

Plasmid pBR322 was cleaved with PvuII and BalI (each providing a blunt end), ligated with a T4DNA ligase and used to transform the E. coli strain WA802. The transformants were screened for resistance to both ampicillin and tetracycline, and from the active transformants the plasmid pBR322ΔBalI lacking the small PvuII-BalI DNA fragment on pBR322 was isolated.

The plasmid pBR 322ΔBalI was cleaved with HindIII and AhaIII. The plasmid pPLT4TNFST8 that was obtained in Reference Example 2 was partially digested with EcoRI, filled in at the EcoRI cohesive end (see Reference Example 3) and cleaved with HindIII. The two DNA fragments were ligated with a T4DNA ligase. The ligation product was used to transform the E. coli strains WA802 and W3110 and the transformants were screened for tetracycline-resistant clones. Plasmid DNA was isolated from the clones and restriction enzyme analysis verified the construction of the desired plasmid pT4TNFST8rop⁻. The E. coli strains WA802 and W3110 having the plasmid pT4TNFST8rop⁻ were named WA802/pT4TNFST8rop⁻ and W3110/pT4TNFST8rop⁻, respectively, and their capability of TNF production was determined.

Reference Example 2 Construction of Plasmid pUC-P_(L)-trp a

A repressor cI region of λcI857 phage DNA (Takara Shuzo, Japan) was introduced to a multi-cloning site of plasmid pUCl9 (Takara Shuzo, Japan) to construct plasmid pUC-cI. Next, an ArtlI-EcoRI fragment containing P_(L) promotor region was prepared from plasmid pS224-3, and was inserted into ArtII/EcoRI sites of the plasmid pUC-C_(I) to construct plasmid pUC-P_(L). To the plasmid pUC-P_(L), synthetic trp a terminator:

(5′-TCGACAGCCCGCCTAATGAGCGGGCTTTTTTTTC-3′      3′-GTCGGGCGGATTACTCGCCCGAAAAAAAAGAGCC-5′)

having AvaI and SalI cohesive ends was inserted to construct plasmid pUC-P_(L) trp a.

Reference Example 3 Construction of Plasmid pS224-3

1) Preparation of cDNA Library, and Isolation and Identification of α-hANP Gene

(1-a) Preparation of cDNA Library

From two human atrium cordis obtained from an 82 years old female and 61 year old male, 1 mg of RNA was extracted with 4M guanidium thiocyanate according to a method of Chirgwin et al. (Chirgwin, J. M. et. al., Biochemistry 18, 5294-5299, 1979). The RNA was then subjected to an oligo (dT) cellulose column using 10 mM Tris-HCl buffer, pH 7.2, containing 0.5 mM LiCl, 10 mM EDTA and 0.5% SDS as a binding buffer, and 75 μg of poly (A)⁺RNA (mRNA) was isolated (Nakazato, H. & Edmonds, D. S., Meth. Enzym. 29, 431-443, 1974). 15 μg of the poly (A)⁺RNA and 4.2 μg of vector primer DNA were used to prepare a cDNA library (plasmids) according to the Okayama-Berg method (Mol. Cell Biol. 2, 161-170, 198), and the cDNA library was used to transform E. coli WA802. The transformants were screened on an LB-agar medium supplemented with 40 γ/ml of ampicillin, and about 40,000 colonies of ampicillin resistant transformants were obtained per microgram of starting mRNA.

(1-b) Isolation of α-hANP Clone

About 40,000 colonies were replicated on a nitrocellulose filter, and the filter was incubated on an LB agar plate supplemented with 40 γ/ml of ampicillin at 37° C. for 6 hours. The filter was transferred onto an LB agar plate supplemented with 180 γ/ml of chloramphenicol, and incubated at 37° C. over night. The colonies on the filter were lysated with 0.5N NaOH, and neutralized to pH 7.0, and the filter was soaked in 0.5M Tris-HCl buffer, pH 7.0, containing 1.5 N NaCl, and in 3×SCC (0.15 M NaCl. 0.05M sodium citrate) for 5 minutes respectively. Finally, cell debris on the filter was removed with a paper towel, and the filter was air-dried and then baked at 80° C. for 2 hours. The filters were then subjected to hybridization with a mixture of probes I and II consisting of chemically synthesized 14-mer oligonucleotides labeled with ³²p at their 5′-end (Grunstein, M. & Hogness, D. S., Proc. Natl. Acad. Sci. USA, 72, 3961-3965, 1975).

         T  T 3′-TACCTGGTAGCC-5′ PROBE I         AC  T          A               T 3′-TACCTGTCTTAGCC-5′ PROBE II         A  C  A

The 14-mer oligonucleotides used as a probe are possibly complemental with mRNA coding for an amino acid sequence Met-Asp-Arg-Ile-Gly and have been labeled with ³²p at their 5′-end using ³²p γ-ATP and T4 kinase and have a specific activity of 1 to 3×10⁶ cpm/p mole. The hybridization was carried out in 3×SCC containing 1×Denhardts (0.2% BSA. Armour Pharmaceutical Company; 0.2% Ficol, Sigma; and 0.2% polyvinyl pyrrolidone, Wako Jyunyaku), 0.1% SDS and 50 μg/ml salmon testis DNA, at 38° C. for 16 hours. The filter was then washed with 3SCC containing 0.1% SDS, air-dried, and placed in contact with an X-ray film. As a result, 85 positive clones were observed on the film. The 85 positive clones were then subjected to the colony hybridization using the same procedure as described above, except that the probe I and probe II were separately used at 40° C. and 38° C. for each probe. As a result, 23 clones were obtained which hybridize with the probe II but do not hybridize with the probe I. Among these 23 clones 8 clones were used to isolate plasmid DNA according to a conventional method. The isolated plasmid DNAs were sequenced using the probe II as the primer according to a dideoxy chain termination method (Sanger F. et al, Proc. Natl. Acad. Sci. USA, 74, 4563-5467, 1977). As a result, all of the plasmids contained a base sequence corresponding to a part of an amino acid sequence of α-hANP and, consequently, the above-mentioned 8 clones were confirmed to have a plasmid containing cDNA of α-hANP. Among the 8 plasmids, 2 plasmids having a longer insert containing cDNA of γ-hANP were selected, and designated as phANP1 and phANP82. The inserts of plasmids phANP1 and phANP82 were sequenced. As a result, the plasmids phANP1 and phANP82 contained an insert of about 950 bp and an insert of about 850 bp, respectively.

2) Construction of γ-hANP Gene Expression Vector

(2-1) Insertion of γ-hANP Gene into M13 DNA

0.44 μg of M13 mp8 RF-DNA was cleaved with 16 units of PstI in 20 μl of Medium-Salt Buffer (10 mM Tris-HCl buffer, pH 7.5, containing 50 mM NaCl, 10 mM MgCl₂, 1 mM DTT) at 37° C. for 1 hour. The mixture was then heated at 65° C. for 10 minutes to stop the enzyme reaction. On the other hand, 20 μg of plasmid phANPl DNA was cleaved with 160 units of PstI in 100 μl of the Medium Salt Buffer at 37° C. for 1 hour, and the reaction mixture was subjected to 1% agarose gel electrophoresis. A part of the gel containing a DNA fragment corresponding to about 700 bp was cut to obtain an agarose piece, and the DNA fragment was extracted by the electro-elution method and purified.

66 ng of the DNA fragment from M13 mp8 RF-DNA and 1 μg of the 700 bp DNA fragment were ligated using 5.6 units of T4 DNA ligase (Takara Shuzo, Japan) in 20 μl of ligation buffer (20 mM Tris-HCl buffer, pH 7.6, containing 10 mM MgCl₂, 1 mM ATP, 5 mM DTT) at 14° C. for 16 hours. E. coli JM103 cells were treated with CaCl₂ according to a conventional method to obtain a suspension of the E. coli cells in 50 mM CaCl₂, and the ligation mixture prepared as above (20 μl) was added to the E. coli suspension to transform the E. coli.

The transformant clones were screened as follows. The suspension containing transformant E. coli cells was diluted in YT soft agar medium containing X-Gal and IPTG (prepared by adding 10 μl of 10 mM IPTG, 50 μl of 2% X-gal and 0.2 ml of E. coli JM103 suspension grown in a logarithmic growth phase into 3 ml of solution containing 0.6% agar, 0.8% Bacto trypton, 0.5% yeast extract and 0.5% NaCl). 0.3 ml of the diluted suspension was spread on YT agar medium (1.5% agar, 0.8% Bacto trypton, 0.5% yeast extract and 0.5% NaCl), and incubated at 37° C. for 16 hours to form plaques. Among the plaques, 10 μlaques were selected, and inoculated into 2×YT liquid medium (1.6% Bacto trypton, 1% yeast extract and 1.0% NaCl) and cultured at 37° C. for 8 hours. 1 ml of the cultured medium was centrifuged at 10,000 rpm for 10 minutes to recover a supernatant containing phage. The phage DNA (single strand DNA) was isolated and purified as follows.

To 800 μl of the phase liquid, 200 μl of 20% polyethylene glycol (PEG 6000) containing 2.5N NaCl was added, and the mixture was allowed to stand at room temperature for 20 minutes and centrifuged at 10,000 rpm for 5 minutes to precipitate the phage. The precipitated phage was dissolved in 100 μl of TE buffer (10 mM Tris-HCl, pH 8.0, 1 mM EDTA), and to the solution 50 μl of phenol saturated with water was added, the mixture was vigorously stirred for 5 minutes, and centrifuged at 10,000 rpm for 5 minutes. After sampling 80 μl of the aqueous phase, to the aqueous phase 3 μl of 3M sodium acetate, pH 8.0, and 200 μl of ethanol was added, and the mixture was cooled at −70° C. for 10 minutes, and then centrifuged at 10,000 rpm for 10 minutes to precipitate DNA. The precipitated DNA was washed once with ethanol, and dissolved in 50 μl of the above-mentioned TE buffer. A part of a base sequence of each phage DNA was sequenced according to the dideoxy chain termination method (Methods in Enzymology, 65, 560-580, 1980, Academic Press, New York), and among 10 clones, 2 clones containing a lower strand (DNA fragment having a base sequence complementary to mRNA) were selected. The phage DNA thus obtained were used as a template for in vitro mutation.

(2-b) Incorporation of EcoRI Cleavaqe Site and Translation Initiation Codon by In-vitro Mutation

To 5 μl of the single strand phage DNA solution described above, 1 μl of 0.2M Tris-HCl buffer, pH 7.5, containing 0.1M MgCl₂ and 0.5M NaCl, and 2 μl of water, were added 2 μl of solution containing 10 pmole of 36-mer chemically synthesized DNA fragment (5′-CTCCTAGGTCAGGAATTCATGAATCCCATGTACAAT-3′) phosphorylated at the 5′ end to form 10 μl of a mixture. The mixture was heated at 65° C. for 5 minutes, and allowed to stand for 10 minutes at room temperature.

To the mixture, 1 μl of 0.2M Tris-HCl buffer (pH 7.5) containing 0.1M MgCl, 2 μl of 0.1M DTT, 1 μl of 10 mM ATP, 2 μl each of 10 mM DATP, dDTP, dCTP and dTTP, 2 μl of water, 5 units of DNA polymerase I Klenow fragment (Boehringger Manheim) and 2.8 units of T4 DNA ligase (Takara Shuzo) were added, and the mixture was incubated at 15° C. for 16 hours. 20 μl of the reaction mixture was used to transform E. coli JM103.

As described above for the preparation of phage DNA, plagues were formed on a YT soft agar medium, and 48 clones were selected. The clones were inoculated to 2×YT medium, and cultured at 37° C. for 8 hours. 1 ml of the cultured medium was centrifuged at 10,000 rpm for 10 minutes to recover the supernatant as phage solution. On the other hand, RF-DNA was extracted and isolated from the precipitated cells according to the alkaline extraction method (Birnboim, H. C. & Doly, J., Nucl. Acid. Res., 7, 1513-1523, 1979). The RF-DNA was then cleaved with 4.2 units of EcoRI (Takara Shuzo) in EcoRI buffer (100 mM Tris-HCl, pH 7.5, 50 mM NaCl, 5 mM MgCl₂) at 37° C. for 1 hour. The reaction mixture was subjected to 2% agarose gel electrophoresis, and a clone providing a DNA fragment of about 530 bp was selected. The clone was designated as M13 mp8-hANP525 .

To 400 ml of 2×YT liquid medium, 0.4 ml of culture of E. coli JM103 infected with the above-mentioned phage clone and 4 ml of a not-infected culture of E. coli JM103 were inoculated. The medium was then incubated at 37° C. for 12 hours. The cultured medium was centrifuged to obtain an infected cell precipitation and a supernatant phage solution. From the infected cells, RF-DNA was obtained by a density-gradient centrifugation method using cesium chloride and ethidium bromide according to a conventional method. On the other hand, from the supernatant phage solution phage DNA was obtained, and the phage DNA was sequenced according to the dideoxy chain termination method. As a result, it was confirmed that a translation initiation codon ATG and EcoRI cleavage recognition site GAATTC, i.e., a base sequence GAATTC ATG, were inserted immediately upstream of the γ-hANP gene.

(2-c) Construction of Expression Vector for γ-hANP Gene

An expression plasmid pS223-3 was constructed from plasmid pS20 and M13mp8-hANP525. The starting plasmid pS20 was constructed by the inventors, and E. coli N4380/pS20 containing the plasmid pS20 was designated as SBM271, and deposited as FERM BP-535 as described above. The plasmid pS20 contains λ phase P_(L) promotor, and can express a foreign gene inserted to a site downstream of the promotor under the control of the promotor.

The plasmid pS20 was constructed as follows. Bacteriophage λC1857 DNA was cleaved with BamHI and HindIII to obtain a 2.4 kb DNA fragment containing the λP_(L) promotor. The DNA fragment was inserted into a region of HindIII-BamHI in pBR322 to obtain a plasmid which is substantially the same as the plasmid pKO 30 described in Nature 292, 128, 1981. To the Hpa I cleavage site of the plasmid thus obtained, 1.3 Kb Hae III DNA fragment containing NutR, tR₁, CII and a part of O protein derived from bacteriophage λcy3048 (from Dr. Hiroyuki Shimatake, Medical Department, Toho University) was inserted to obtain plasmid (pS9), wherein CII is present in the direction the same as the transcription direction of λP_(L). The plasmid (pS9) was cleaved with Bgl II and Rsa I to obtain a 0.65 Kb DNA fragment containing P_(L) promotor, DNA sequence of protein N′ which is a part of an N protein lacking a C terminal, and the Shine-Dalgarno sequence (SD) of a CII gene. The Rsa I and of the 0.65 Kb DNA fragment was added with the Eco RI linker:

—CGGAATTCCG—

—GCCTTAAGGC—

(New England Biolabos, Inc.), and then the Bgl II end of the same DNA fragment was converted to a blunt end with T4 DNA polymerase. The DNA fragment thus obtained was ligated with a DNA fragment prepared by Eco RI cleavage of plasmid pBR322 and conversion of the pBR322 ends to blunt ends to form a plasmid (pS13). In the plasmid (pS13), the P_(L) promotor is oriented in the direction the same as the transcription direction of the tetracycline resistant gene (Tc^(r)) derived from pBR322. The plasmid (pS13) was cleaved with Eco RI and Sal I, and a large fragment was isolated. The large fragment was then ligated with a DNA fragment containing a foreign gene, i.e., human γ-interferon gene GIF, which fragment was prepared by cleavage of plasmid pGIF4 with Eco RI and Sal I. The plasmid pGIF4 was disclosed in Japanese Unexamined Patent Publication No. 58-201995 (USP. Serial No. 496176), and E. coli containing the plasmid was designated as SBMG 105 and deposited at the FRI under the Budapest Treaty on the International Recognition of the Deposit of Microorganisms for the Purpose of Patent Procedure as FERM BP-282 on May 6, 1982.

Plasmid pS20 was cleaved with Eco RI, and hydrolyzed with an exonuclease Bal 31 to form DNA fragments having various lengths. The DNA fragments were ligated with Xba I linker (from New England Biolabos Inc.; dCTCTAGAG) to obtain plasmid pS20X. The plasmid pS20X was cleaved with Xba I and Sal I to delete any Xba I-Sal I short fragments. On the other hand, plasmid pIN4GIF54 was cleaved with Xba I and Sal I to obtain a short Xba I-Sal I fragment containing human γ-interferon gene, which short fragment was then inserted to the above-mentioned cleaved pS20X in place of the deleted Xba I-Sal I fragment to form plasmids. Among the plasmids thus formed, a plasmid which can effectively express the human γ-interferon gene when transformed into E. coli was designated as pS83-3. The above-mentioned plas mid pIN4GIF54 and a method for measuring an amount of γ-interferon were disclosed in Japanese Unexamined Patent Publication No. 60-24187 (U.S. Pat. Ser. No. 632204). Plasmid sP83-3 was cleaved with Eco RI and Sal I to delete the Eco RI-Sal I short fragment consisting of the human γ-interferon gene (GIF). The plasmid M13mp8-hANP525 was cleaved with Eco RI and Sal I to obtain an about 510 bp Eco RI-Sal I fragment containing γ-hANP gene, which fragment was then inserted to the cleaved pS83-3 in place of the deleted Eco RI-Sal I fragment consisting of GIF to form plasmid pS223-3. The plasmid pS223-3 contains an λP_(L) promotor region, SD sequence of E. coli 1 pp gene, and γ-hANP gene, in this order.

Another γ-hANP gene expression vector pS224-3 was constructed as follows. The plasmid pS83-3 was cleaved with Xba I and Eco RI to delete the SD sequence of the lpp gene, and in place of the delected SD sequence of the lpp gene, a chemically synthesized DNA fragment AGGAGGT with Xba I and Eco RI cohesive ends, which is the SD sequence of the bacteriophage MS2A protein gene, was inserted into the cleaved pS83-3 to form plasmid pS83-3. The plasmid pS84-3 DNA was cleaved with Eco RI and Sal I to delete the Eco RI-Sal I short fragment consisting of GIF. The plasmid M13mp8-hANP525 DNA was cleaved with Eco RI and Sal I to obtain an about 510 bp Eco I-Sal RI fragment containing the t-HANP gene, which fragment was then inserted into the cleaved pS84-3 DNA in place of the deleted Eco RI-Sal I fragment consisting of GIF to obtain plasmid pS224-3. The plasmid pS224-3 thus obtained contained a λP_(L) promotor region, SD sequence of MS2A, and γ-hANP gene, in this order. E. coli N4380 transformed with the plasmid pS224-3 was designated as E. coli N4380/pS244-3.

Reference Example 4 Construction of pIN4GIF54

Plasmid pIN4GIF54 was constructed from (1) DNA fragment containing the lipoprotein gene promotor region (indicated by lpp in the figure) as obtained by digestion of the plasmid pINIA2 with the restriction enzymes XbaI and PstI, (2) oligonucleotide having XbaI and EcoRI cohesive ends and (3) DNA fragment containing the hINF-γ gene as obtained by digestion of the plasmid pGIF54 with EcoRI and PstI. The procedure followed was as described hereinbelow. The restriction enzymes used were all products of Takara Shuzo K. K.

A) Preparation of XbaI-PstI DNA Fragment of pINI-A2

The plasmid pINI-A2 is a gift from Dr. Inoue of New York State University. A host Escherichia coli strain obtained by transformation with said plasmid has been named JA221/pINI-A2 and deposited with the Fermentation Research Institute, 1-3, Higashi 1-chome Tsukuba-shi, Ibaraki, Japan, under Deposit No. FERM BP-320, on Jul. 18, 1983 under the Budapest treaty.

The pINI-A2 DNA (3 μg) was digested with 15 units each of XbaI and PstI in 150 μl of 1×TA solution (33 mM Tris acetate buffer pH 7.6, 66 mM potassium acetate, 10 mM magnesium acetate and 0.5 mM dithiothreitol) at 37° C. for 60 minutes. The reaction mixture was subjected to 1.0% agarose gel electrophoresis and a gel portion located at the position corresponding to about 980 b.p. (base pairs) was cut out and placed in a dialysis tube, and the XbaI-PstI DNA fragment was eluted by electrophoresis. After removal of ethidium bromide from the eluate by adding an equal amount of phenol thereto, 2.5 volumes of ethanol was added. After standing at −80° C. for 30 minutes, the mixture was centrifuged at 10,000 rpm for 10 minutes, whereby the DNA fragment was obtained as an ethanol precipitate. To this ethanol precipitate was added 10 μl of distilled water for dissolving the DNA fragment.

B) Preparation of EcoRI-PstI DNA Fragment of pGIF54

Plasmid pGIF54 is essentially the same plasmid as pGIF4 disclosed in Japanese Patent Application No. 86,180/1982. An Escherichia coli transformant, WA802/pGIF4, obtained by transformation with said plasmid containing the chemically synthesized gene coding for the amino acid sequence of hIFN-γ has been named SBMG105 and deposited with the Fermentation Research Institute, the Agency of Industrial Science and Technology as FERM P-6522 on May 6, 1982, and transferred to deposition under the Budapest treaty, as FERM BP-282, on May 2, 1983.

The pGIF54 DNA (3 μg) was digested with 15 units each of EcoRI and PstI in 30 μl of 1×TA solution at 37° C. for 60 minutes, followed by 0.7% agarose gel electrophoresis, whereby an EcoRI-PstI DNA fragment of about 3.4 Kb was eluted from the gel. The eluate was subjected to phenol treatment and ethanol precipitation in the same manner as above. To the ethanol precipitate, 10 μl of distilled water was added for dissolution of the DNA fragment.

C) Preparation of Oligonucleotide having XbaI and EcoRI Cohesive Ends

For the expression of complete hINF-γ protein, an oligonucleotide having the Shine-Dalgarno (SD) sequence downstream from the XbaI cleavage site of pINIA2 and further having an EcoRI cohesive end, namely the oligonucleotide,

      SP 5′CTAGAGGTAG3′     3′TCCATCTTAA5′

XbaI cohesive end EcoRI cohesive end was synthesized by the solid phase method. The synthetic procedure has been disclosed in detail in Japanese Patent Application No. 86,180/1982.

The above oligonucleotide (100 picomoles) was phosphorylated at the 5′-OH in 30 μl of a kinase reaction solution (50 mM Tris hydrochloride buffer, pH 8.0, 10 mM MgCl₂, 10 mM dithiothreitol), with 2 units of T4 polynucdeotide kinase (Takara Shuzo K. K.) added, at 37° C. for 60 minutes.

D) Construction of pIN4GIF54

The plasmid pIN4GIF54 was constructed by ligation of the three DNA fragments prepared above in accordance with the following procedure. Thus, to a mixture of 5 μl of a solution of the XbaI-PstI DNA fragment of pINIA2 (solution of the ethanol precipitate in 10 μl of distilled water), 5 μl of a solution of the EcoRI-PstI DNA fragment of pGIF54 (solution of the ethanol precipitate in 10 μl of distilled water) and 3 μl of a solution of the phosphorylated oligonucleotide (10 picomoles), there were added 2 μl of a ligation reaction medium 10-fold higher in concentration (20 mM Tris hydrochloride buffer, pH 7.6, 10 mM MgCl₂), 2 μl of 4 mM ATP and 1 μl of T4 DNA ligase (Boehringer Mannheim) (5 units), and the ligation was carried out at 16° C. overnight.

(2) Transformation of Escherichia coli

A) Transformation of Escherichia coli WA802

Escherichia coli WA802 was cultured in 2.0 ml of L-broth at 37° C. overnight, 0.3 ml of the culture broth was added to 30 ml of L-broth, and shake culture was performed at 37° C. for 2 hours, followed by centrifugation at 3,000 rpm for 10 minutes. To the thus-obtained cells was added 10 ml of 50 mM CaCl₂ for suspending the cells, and centrifugation was conducted at 3,000 rpm for 10 minutes. To the thus-obtained cells was added 1.0 ml of 50 mM CaCl₂ solution, and the mixture was allowed to stand in an ice bath for 60 minutes. To 0.2 ml of this suspension of Ca⁺⁺-treated cells was added 10 μl of the ligation reaction mixture obtained in Reference Example 4-D (containing the above-mentioned three DNA fragments ligated), the mixture was allowed to stand in an ice bath for 60 minutes, them 2 ml of L-broth was added and incubation was conducted at 37° C. for 60 minutes. The culture broth was used for plating on nutrient agar medium (BBL) containing 40 μg/ml of ampicillin. After incubation at 37° C. overnight, ampicillin-resistant transformants were selected. One of the transformants obtained was used for plasmid DNA separation therefrom by the conventional method (cleared lysate method). The base sequence of the DNA at and around the XbaI-EcoRI region inserted was determined by the Maxam-Gilbert method (Methods in Enzymology, 65: 499-560, 1980) and it was confirmed that the DNA had the desired DNA base sequence. This plasmid was named pIN4GIF54 and the transformant Escherichia coli strain carrying the same was named WA802/pIN4GIF54. 

What is claimed is:
 1. An isolated C-terminal α-amidating enzyme, having the following amino acid sequence (IV): Ser Leu Ser Asn Asp Cys Leu Gly Thr Thr Arg Pro Val Met Ser Pro Gly Ser Ser Asp Tyr Thr Leu Asp Ile Arg Met Pro Gly Val Thr Pro Thr Glu Ser Asp Thr Tyr Leu Cys Lys Ser Tyr Arg Leu Pro Val Asp Asp Glu Ala Tyr Val Val Asp Tyr Arg Pro His Ala Asn Met Asp Thr Ala His His Met Leu Leu Phe Gly Cys Asn Val Pro Ser Ser Thr Asp Asp Tyr Trp Asp Cys Ser Ala Gly Thr Cys Asn Asp Lys Ser Ser Ile Met Tyr Ala Trp Ala Lys Asn Ala Pro Pro Thr Lys Leu Pro Glu Gly Val Gly Phe Gln Val Gly Gly Lys Ser Gly Ser Arg Tyr Phe Val Leu Gln Val His Tyr Gly Asp Val Lys Ala Phe Gln Asp Lys His Lys Asp Cys Thr Gly Val Thr Val Arg Ile Thr Pro Glu Lys Gln Pro Leu Ile Ala Gly Ile Tyr Leu Ser Met Ser Leu Asn Thr Val Val Pro Pro Gly Gln Glu Val Val Asn Ser Asp Ile Ala Cys Leu Tyr Asn Arg Pro Thr Ile His Pro Phe Ala Tyr Arg Val His Thr His Gln Leu Gly Gln Val Val Ser Gly Phe Arg Val Arg His Gly Lys Trp Thr Leu Ile Gly Arg Gln Ser Pro Gln Leu Pro Gln Ala Phe Tyr Pro Val Glu His Pro Leu Glu Ile Ser Pro Gly Asp Ile Ile Ala Thr Arg Cys Leu Phe Thr Gly Lys Gly Arg Met Ser Ala Thr Tyr Ile Gly Gly Thr Ala Lys Asp Glu Met Cys Asn Leu Tyr Ile Met Tyr Tyr Met Asp Ala Ala His Ala Thr Ser Tyr Met Thr Cys Val Gln Thr Gly Asn Pro Lys Leu Phe Glu Asn Ile Pro Glu Ile Ala Asn Val Pro Ile Pro Val Ser Pro Asp Met Met Met Met Met Met Met Gly His Gly His-C

wherein C represents the following amino acid sequence (V): Gly Asp Pro Leu Glu Ser Thr Cys Arg His Ala, or

the following amino acid sequence (VI): His His Thr Glu Ala Glu -X- Glu -Y- Asn Thr -Z- Leu Gln Gln Pro Lys-D

wherein X represents Ala or Pro; Y represents Thr or Lys; Z represents Ala or Gly; and D is absent or represents the following amino acid sequence (VII), (VIII), (IX) or (X): (VII):\\Arg Glu Glu Glu Glu Val Leu Asn Gln Asp Val His Leu Glu Glu Asp Thr Asp Trp Pro Gly Val Asn Leu Lys Val Gly Gln Val Ser Gly Leu Ala Leu Asp Pro Lys Asn Asn Leu Val Ile Phe His Arg Gly Asp His Val Trp Asp Glu Asn Ser Phe Asp Arg Asn Phe Val Tyr Gln Gln Arg Gly Ile Gly Pro Ile Gln Glu Ser Thr Ile Leu Val Val Asp Pro Asn Thr Ser Lys Val Leu Lys Ser Thr Gly Gln Asn Leu Phe Phe Leu Pro His Gly Leu Thr Ile Asp Arg Asp Gly Asn Tyr Trp Val Thr Asp Val Ala Leu His Gln Val Phe Lys Val Gly Ala Glu Lys Glu Thr Pro Leu Leu Val Leu Gly Arg Ala Phe Gln Pro Gly Ser Asp Arg Lys His Phe Cys Gln Pro Thr Asp Val Ala Val Asp Pro Ile Thr Gly Asn Phe Phe Val Ala Asp Gly Tyr Cys Asn Ser Arg Ile Met Gln Phe Ser Pro Asn Gly Met Phe Ile Met Gln Trp Gly Glu Glu Thr Ser Ser Asn Leu Pro Arg Pro Gly Gln Phe Arg Ile Pro His Ser Leu Thr Met Ile Ser Asp Gln Gly Gln Leu Cys Val Ala Asp Arg Glu Asn Gly Arg Ile Gln Cys Phe His Ala Lys Thr Gly Glu Phe Val Lys Gln Ile Lys His Gln Glu Phe Gly Arg Glu Val Phe Ala Val Ser Tyr Ala Pro Gly Gly Val Leu Tyr Ala Val Asn Gly Lys Pro Tyr Tyr Gly Asp Ser Thr Pro Val Gln Gly Phe Met Leu Asn Phe Ser Asn Gly Asp Ile Leu Asp Thr Phe Ile Pro Ala Arg Lys Asn Phe Glu Met Pro His Asp Ile Ala Ala Gly Asp Asp Gly Thr Val Tyr Val Gly Asp Ala His Ala Asn Ala Val Trp Lys Phe Ser Pro Ser Lys Ala Glu His Arg Ser Val Lys Lys Ala Gly Ile Glu Val Glu Glu Ile Thr Glu Thr Glu Ile Phe Glu Thr His Met Arg Ser Arg Pro Lys Thr Asn Glu Ser Val Gly Gln Gln Thr Gln Glu Lys Pro Ser Val Val Gln Glu Ser Ser Ala Gly Val Ser Phe Val Leu Ile Ile Thr Leu Leu Ile Ile Pro Val Val Val Leu Ile Ala Ile Ala Ile Phe Ile Arg Trp Arg Lys Val Arg Met Tyr Gly Gly Asp Ile Gly His Lys Ser Glu Ser Ser Ser Gly Gly Ile Leu Gly Lys Leu Arg Gly Lys Gly Ser Gly Gly Leu Asn Leu Gly Thr Phe Phe Ala Thr His Lys Gly Tyr Ser Arg Lys Gly Phe Asp Arg Leu Ser Thr Glu Gly Ser Asp Gln Glu Lys Asp Asp Asp Asp Asp Gly Ser Asp Ser Glu Glu Glu Tyr Ser Ala Pro Pro Ile Pro Pro Val Ser Ser Ser; (VIII): Arg Glu Glu Glu Glu Val Leu Asn Gln Asp Val His Leu Glu Glu Asp Thr Asp Trp Pro Gly Val Asn Leu Lys Val Gly Gln Val Ser Gly Leu Ala Leu Asp Pro Lys Asn Asn Leu Val Ile Phe His Arg Gly Asp His Val Trp Asp Glu Asn Ser Phe Asp Arg Asn Phe Val Tyr Gln Gln Arg Gly Ile Gly Pro Ile Gln Glu Ser Thr Ile Leu Val Val Asp Pro Asn Thr Ser Lys Val Leu Lys Ser Thr Gly Gln Asn Leu Phe Phe Leu Pro His Gly Leu Thr Ile Asp Arg Asp Gly Asn Tyr Trp Val Thr Asp Val Ala Leu His Gln Val Phe Lys Val Gly Ala Glu Lys Glu Thr Pro Leu Leu Val Leu Gly Arg Ala Phe Gln Pro Gly Ser Asp Arg Lys His Phe Cys Gln Pro Thr Asp Val Ala Val Asp Pro Ile Thr Gly Asn Phe Phe Val Ala Asp Gly Tyr Cys Asn Ser Arg Ile Met Gln Phe Ser Pro Asn Gly Met Phe Ile Met Gln Trp Gly Glu Glu Thr Ser Ser Asn Leu Pro Arg Pro Gly Gln Phe Arg Ile Pro His Ser Leu Thr Met Ile Ser Asp Gln Gly Gln Leu Cys Val Ala Asp Arg Glu Asn Gly Arg Ile Gln Cys Phe His Ala Lys Thr Gly Glu Phe Val Lys Gln Ile Lys His Gln Glu Phe Gly Arg Glu Val Phe Ala Val Ser Tyr Ala Pro Gly Gly Val Leu Tyr Ala Val Asn Gly Lys Pro Tyr Tyr Gly Asp Ser Thr Pro Val Gln Gly Phe Met Leu Asn Phe Ser Asn Gly Asp Ile Leu Asp Thr Phe Ile Pro Ala Arg Lys Asn Phe Glu Met Pro His Asp Ile Ala Ala Gly Asp Asp Gly Thr Val Tyr Val Gly Asp Ala His Ala Asn Ala Val Trp Lys Phe Ser Pro Ser Lys Ala Glu His Arg Ser Val Lys Lys Ala Gly Ile Glu Val Glu Glu Ile Thr Glu Thr Glu Ile Leu; (IX):Arg Glu Glu Glu Glu Val Leu Asn Gln Asp Val His Leu Glu Glu Asp Thr Asp Trp Pro Gly Val Asn Leu Lys Val Gly Gln Val Ser Gly Leu Ala Leu Asp Pro Lys Asn Asn Leu Val Ile Phe His Arg Gly Asp His Val Trp Asp Glu Asn Ser Phe Asp Arg Asn Phe Val Tyr Gln Gln Arg Gly Ile Gly Pro Ile Gln Glu Ser Thr Ile Leu Val Val Asp Pro Asn Thr Ser Lys Val Leu Lys Ser Thr Gly Gln Asn Leu Phe Phe Leu Pro His Gly Leu Thr Ile Asp Arg Asp Gly Asn Tyr Trp Val Thr Asp Val Ala Leu His Gln Val Phe Lys Val Gly Ala Glu Lys Glu Thr Pro Leu Leu Val Leu Gly Arg Ala Phe Gln Pro Gly Ser Asp Arg Lys His Phe Cys Gln Pro Thr Asp Val Ala Val Asp Pro Ile Thr Gly Asn Phe Phe Val Ala Asp Gly Tyr Cys Asn Ser Arg Ile Met Gln Phe Ser Pro Asn Gly Met Phe Ile Met Gln Trp Gly Glu Glu Thr Ser Ser Asn Leu Pro Arg Pro Gly Gln Phe Arg Ile Pro His Ser Leu Thr Met Met Gly Ile Leu; (X):Arg Glu Glu Glu Glu Val Leu Asn Gln Asp Val His Leu Glu Glu Asp Thr Asp Trp Pro Gly Val Asn Leu Lys Val Gly Gln Val Ser Gly Leu Ala Leu Asp Pro Lys Asn Asn Leu Val Ile Phe His Arg Gly Asp His Val Trp Asp Glu Asn Ser Phe Asp Arg Asn Phe Val Tyr Gln Gln Arg Gly Ile Gly Pro Ile Gln Glu Ser Thr Ile Leu Val Val Asp Pro Asn Thr Ser Lys Val Leu Lys Ser Thr Gly Gln Asn Leu Phe Phe Leu Pro His Gly Leu Thr Ile Asp Arg Asp Gly Asn Tyr Trp Val Thr Asp Val Ala Leu His Gln Val Phe Lys Val Gly Ala Glu Lys Glu Thr Pro Leu Leu Val Leu Gly Arg Ala Phe Gln Pro Gly Ser Asp Arg Lys His Phe Cys Gln Pro Thr Asp Val Ala Val Asp Leu Gln Ala Cys Leu Ile Asn.


2. An isolated C-terminal α-amidating enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid sequence (VI), wherein X represents Ala, Y represents Thr, and Z represents Ala, and D represents the amino acid sequence (VII).
 3. An isolated C-terminal α-amidating enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid sequence (VI), wherein X represents Ala, Y represents Thr, and Z represents Ala, and D represents the amino acid sequence (VIII).
 4. An isolated C-terminal α-amidating enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid sequence (VI), wherein X represents Ala, Y represents Thr, and Z represents Ala, and D represents the amino acid sequence (IX).
 5. An isolated C-terminal α-amidating.enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid sequence (VI), wherein X represents Ala, Y represents Thr, and Z represents Ala, and D represents the amino acid-sequence (X).
 6. An isolated C-terminal α-amidating enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid sequence (VI), wherein X represents Ala, Y represents Thr, and Z represents Ala, and D is absent.
 7. An isolated C-terminal α-amidating enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid-sequence (VI), wherein X represents Pro, Y represents Lys, and Z represents Gly, and D is absent.
 8. An isolated C-terminal α-amidating enzyme according to claim 1, having the amino acid sequence (IV) wherein C represents the amino acid sequence (V).
 9. An isolated C-terminal α-amidating enzyme according to claim 1, wherein said enzyme is produced by a recombinant DNA technique.
 10. An isolated C-terminal α-amidating enzyme of Xenopus laevis wherein said C-terminal α-amidating enzyme has at least the following amino acid sequence: Ser Leu Ser Asn Asp Cys Leu Gly Thr Thr Arg Pro Val Met Ser Pro Gly Ser Ser Asp Tyr Thr Leu Asp Ile Arg Met Pro Gly Val Thr Pro Thr Glu Ser Asp Thr Tyr Leu Cys Lys Ser Tyr Arg Leu Pro Val Asp Asp Glu Ala Tyr Val Val Asp Tyr Arg Pro His Ala Asn Met Asp Thr Ala His His Met Leu Leu Phe Gly Cys Asn Val Pro Ser Ser Thr Asp Asp Tyr Trp Asp Cys Ser Ala Gly Thr Cys Asn Asp Lys Ser Ser Ile Met Tyr Ala Trp Ala Lys Asn Ala Pro Pro Thr Lys Leu Pro Glu Gly Val Gly Phe Gln Val Gly Gly Lys Ser Gly Ser Arg Tyr Phe Val Leu Gln Val His Tyr Gly Asp Val Lys Ala Phe Gln Asp Lys His Lys Asp Cys Thr Gly Val Thr Val Arg Ile Thr Pro Glu Lys Gln Pro Leu Ile Ala Gly Ile Tyr Leu Ser Met Ser Leu Asn Thr Val Val Pro Pro Gly Gln Glu Val Val Asn Ser Asp Ile Ala Cys Leu Tyr Asn Arg Pro Thr Ile His Pro Phe Ala Tyr Arg Val His Thr His Gln Leu Gly Gln Val Val Ser Gly Phe Arg Val Arg His Gly Lys Trp Thr Leu Ile Gly Arg Gln Ser Pro Gln Leu Pro Gln Ala Phe Tyr Pro Val Glu His Pro Leu Glu Ile Ser Pro Gly Asp Ile Ile Ala Thr Arg Cys Leu Phe Thr Gly Lys Gly Arg Met Ser Ala Thr Tyr Ile Gly Gly Thr Ala Lys Asp Glu Met Cys Asn Leu Tyr Ile Met Tyr Tyr Met Asp Ala Ala His Ala Thr Ser Tyr Met Thr Cys Val Gln Thr Gly Asn Pro Lys Leu Phe Glu Asn Ile Pro Glu Ile Ala Asn Val Pro Ile Pro Val Ser Pro Asp Met Met Met Met Met Met Met Gly His Gly His.


11. An isolated C-terminal α-amidating enzyme of Xenopus laevis according to claim 10, wherein said enzyme is produced by a recombinant DNA technique. 